• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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• 2012.05a
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• pp.95-98
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• 2012

This paper describes a multiphase delay-locked loop (DLL) that generates a 32-phase output clock over the operating frequency range of 40 MHz to 280 MHz. The matrix-based delay line is used for high resolution of 1-bit delay. A calibration scheme, which improves the linearity of a delay line, is achieved by calibrating the nonlinearity of the input stage of the matrix. The multi-phase DLL is fabricated by using 0.11-${\mu}m$ CMOS process with a 1.2 V supply. At the operating frequency of 125MHz, the measurement results shows that the DNL is less than +0.51/-0.12 LSB, and the measured peak-to-peak jitter of the multi-phase DLL is 30 ps with input peak-to-peak jitter of 12.9 ps. The area and power consumption of the implemented DLL are $480{\times}550{\mu}m^2$ and 9.6 mW at the supply voltage of 1.2 V, respectively.

• Proceedings of the IEEK Conference
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• 2005.11a
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• pp.829-832
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• 2005

This paper describes a wide-range dual-loop Delay Locked Loop (DLL) using Voltage Controlled Delay Line (VCDL) based on Transmission Gate(TG) inverters. One loop is used when the minimum VCDL delay is greater than a half of $T_{REF}$, the reference clock period. The other loop is initiated when the minimum delay is less than $0.5{\times}T_{REF}$. The proposed VCDL improves the dynamic operation range of a DLL. The DLL with a VCDL of 10 TG inverters provides a lock range from 70MHz to 700MHz when designed using $0.18{\mu}m$ CMOS technology with 1.8 supply voltage. The DLL consumes 11.5mW for locking operation with a 700MHz reference clock. The proposed DLL can be used for high-speed memory devices and processors, communication systems, high-performance display interfaces, etc.

• Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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• 2012.10a
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• pp.259-262
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• 2012

This paper describes a delay-locked loop (DLL) that generates a 64-phase clock with the operating frequency of 125MHz. The proposed DLL use a $4{\times}8$ matrix-based delay line to improve the linearity of a delay line. The output clock with 64-phase is generated by using a CMOS multiplex and a inverted-based interpolator from 32-phase clock which is the output clock of the $4{\times}8$ matrix-based delay line. The circuit for an initial phase lock, which is independent on the duty cycle ratio of the input clock, is used to prevent from the harmonic lock of a DLL. The proposed DLL is designed using a $0.18-{\mu}m$ CMOS process with a 1.8 V supply. The simulated operating frequency range is 40 MHz to 200 MHz. At the operating frequency of a 125 MHz, the worst phase error and jitter of a 64-phase clock are +11/-12 ps and 6.58 ps, respectively.

• Journal of the Korean Institute of Electrical and Electronic Material Engineers
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• v.17 no.2
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• pp.144-149
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• 2004

Register Controlled DLL with fast locking and low-power consumption, is described in this paper. Delay monitor scheme is proposed to achieve the fast locking and inverter is inserted in front of delay line to reduce the power consumption, also. Proposed DLL was fabricated in a 0.6${\mu}{\textrm}{m}$ 1-poly 3-metal CMOS technology. The proposed delay monitor scheme enables the DLL to lock to the external clock within 4 cycles. The power consumption is 36㎽ with 3V supply voltage at 34MHz clock frequency.

• The Journal of Korean Institute of Communications and Information Sciences
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• v.26 no.12C
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• pp.255-260
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• 2001

This paper describes the design of the Register Controlled DLL(Delay-Locked Loop) that achieves fast locking and low Power consumption using a new locking algorithm. A fashion for a fast locking speed is that controls the two controller in sequence. The up/down signal due to clock skew between a internal and a external clock in phase detector, first adjusts a large phase difference in coarse controller and then adjusts a small phase difference in fine controller. A way for a low power consumption is that only operates one controller at once. Moreover the proposed DLL shows better jitter performance Because using the lock indicator circuit. The proposed DLL circuit is operated from 50MHz to 200MHz by SPICE simulation. The estimated power dissipation is 15mA at 200MHz in 3.3V operation. The locking time is within 7 cycle at all of operating frequency.

• Journal of IKEEE
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• v.3 no.1 s.4
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• pp.50-56
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• 1999

This paper presents a new technique for generating precise clock delays. The technique can obtain finer timing resolution less than the gate delay of the delay chain by locking in multiple clock period. Using this technique, a 250ps of timing resolution could be achieved from a 750ps delay of the single delay stage in a DLL(Delay Locked Loop) structure. The delay chain of the proposed circuit is locked on three times of the clock period and a finer delay resolution than the absolute gate delay is achieved and verified through the simulation.

• The Journal of Korean Institute of Communications and Information Sciences
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• v.23 no.4
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• pp.857-864
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• 1998

The infuluence of Doppler effects on the tracking performance of a noncoherent second-order delay locked loop (DLL) operating on a data modulated signal is investigated. For the perfoermance analysis we consider the tracking accuracy (steady state error and jitter) of the linear DLL and the reliability of the nonlinear loop. The nonlinear analysis concerning the loop reliability makes use of an asympototic expansion for the MTLL(mean time to lose lock) which has been derived by applying the singular perturbation method. In particular, we give optimal loop parameters and the optimal bandwidth of the bandpass filter in the loop arms to achieve a maximum MTLL. Since Doppler effects can be producesd comparatively in LEO system, we can espect the more reliable DLL loop design. by using the results of the circuit simulation, the delay lock loop is synthesized in FPGA, and verified to get the GPS data from the STR-2770 GPS simulator system. So, the synthesized logic circuit is shown be accurately performed.

• The KIPS Transactions:PartA
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• v.10A no.3
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• pp.247-254
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• 2003

This paper describes a Delay Locked Loop (DLL) with low supply voltage and wide lock range for Synchronous DRAM which employs Double Data Rate (DDR) technique for faster data transmission. To obtain high resolution and fast lock-on time, a new type of phase detector is designed. The new counter and lock indicator structure are suggested based on the Dual-clock dual-data Flip Flop (DCDD FF). The DCDD FF reduces the size of counter and lock indicator by about 70%. The delay line is composed of coarse and fine units. By the use of fast phase detector, the coarse delay line can detect minute phase difference of 0.2 nsec and below. Aided further by the new type of 3-step vernier fine delay line, this DLL circuit achieves unprecedented timing resolution of 25psec. This DLL spans wide locking range from 500MHz to 500MHz and generates high-speed clocks with fast lock-on time of less than 5 clocks. When designed using 0.25 um CMOS technology with 1.8V supply voltage, the circuit consumes 32mA at 500MHz locked condition. This circuit can be also used for other applications as well, such as synchronization of high frequency communication systems.

• Journal of the Institute of Electronics and Information Engineers
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• v.50 no.12
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• pp.33-39
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• 2013

There have been studies in improving jitter characteristic of delay locked loop (DLL) even it has a shorter jitter that of phase locked loop (PLL). These studies result in numerous architectures of DLL which improve jitter performance. The paper shows that the jitter characteristic can be improved with various loop filters in DLL. It has been designed with 1.8V $0.18{\mu}m$ CMOS process.

• Journal of the Korea Institute of Information and Communication Engineering
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• v.13 no.11
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• pp.2378-2384
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• 2009

A novel phase-locked loop(PLL) architecture of sub-micron locking time has been proposed. Input frequency is multiplied by using a delay-locked loop(DLL). The input frequency of a PLL is multiplied while the PLL is out of lock. The multiplied input frequency makes the PLL having a wider loop bandwidth. It has been simulated with a $0.18{\mu}m$ 1.8V CMOS process. The simulated locking time is $0.9{\mu}s$ at 162.5MHz and 2.6GHz, input and output frequency, respectively.