In order to improve the performance of arithmetic very large-scale integration (VLSI) sys- tem, a novel structure of quaternary logic gates is proposed based on multiple-valued current mode (MVCM) by using dynamic...In order to improve the performance of arithmetic very large-scale integration (VLSI) sys- tem, a novel structure of quaternary logic gates is proposed based on multiple-valued current mode (MVCM) by using dynamic source-coupled logic (SCL). Its key components, the comparator and the output generator are both based on differential-pair circuit (DPC), and the latter is constructed by using the structure of DPC trees. The pre-charge evaluates logic style makes a steady current flow cut off, thereby greatly saving the power dissipation. The combination of multiple-valued source- coupled logic and differential-pair circuit makes it lower power consumption and more compact. The performance is evaluated by HSPICE simulation with 0.18 ~m CMOS technology. The power dissipa- tion, transistor numbers and delay are superior to corresponding binary CMOS implementation. Mul- tiple-valued logic will be the potential solution for the high performance arithmetic VLSI system in the future.展开更多
This paper presents a novel approach to design robust Source Coupled Logic (SCL) for implementing ultra low power circuits. In this paper, we propose two different source coupled logic structures and analyze the perfo...This paper presents a novel approach to design robust Source Coupled Logic (SCL) for implementing ultra low power circuits. In this paper, we propose two different source coupled logic structures and analyze the performance of these structures with STSCL (Sub-threshold SCL). The first design under consideration is DTPMOS as load device which analyses the performance of Dynamic Threshold SCL (DTSCL) Logic with previous source coupled logic for ultra low power operation. DTSCL circuits exhibit a better power-delay Performance compared with the STSCL Logic. It can be seen that the proposed circuit provides 56% reduction in power delay product. The second design under consideration uses basic current mirror active load device to provide required voltage swing. Current mirror source coupled logic (CMSCL) can be used for high speed operation. The advantage of this design is that it provides 54% reduction in power delay product over conventional STSCL. The main drawback of this design is that it provides a higher power dissipation compared to other source coupled logic structures. The proposed circuit provides lower sensitivity to temperature and power supply variation, with a superior control over power dissipation. Measurements of test structures simulated in 0.18 μm CMOS technology shows that the proposed DTSCL logic concept can be utilized successfully for bias currents as low as 1 pA. Measurements show that existing standard cell libraries offer a good solution for ultra low power SCL circuits. Cadence Virtuoso schematic editor and Spectre Simulation tools have been used.展开更多
采用0.35μm CM O S工艺设计了用于光纤传输系统的低功耗16∶1复接器,实现了将16路155.52M b/s数据复接成一路2.5G b/s的数据输出的功能。该复接器以混合结构形式实现:低速部分采用串行结构,高速部分采用树型结构。具体电路由锁存器、...采用0.35μm CM O S工艺设计了用于光纤传输系统的低功耗16∶1复接器,实现了将16路155.52M b/s数据复接成一路2.5G b/s的数据输出的功能。该复接器以混合结构形式实现:低速部分采用串行结构,高速部分采用树型结构。具体电路由锁存器、选择器及分频器组成,以CM O S逻辑和源极耦合逻辑(SCL)实现。用Sm art SP ICE软件进行仿真的结果显示:在3.3V供电时,整体电路的复接输出最高工作速度可达3.5G b/s,功耗小于300mW。展开更多
A high-speed dual-modulus divide-by-32/33 prescaler has been developed using 0.25 μm CMOS technology. The source-coupled logic (SCL) structure is used to reduce the switching noise and to ameliorate the power-speed t...A high-speed dual-modulus divide-by-32/33 prescaler has been developed using 0.25 μm CMOS technology. The source-coupled logic (SCL) structure is used to reduce the switching noise and to ameliorate the power-speed tradeoff. The proposed prescaler can operate at high frequency with a low-power consumption. Based on the 2.5 V, 0.25 μm CMOS model, simulation results indicate that the maximum input frequency of the prescaler is up to 3.2 GHz. Running at 2.5 V, the circuit consumes only 4.6 mA at an input frequency 2.5 GHz.展开更多
This paper presents the design and analysis of a high speed broadband divide-by-2 frequency divider. The proposed divider is a dynamic source-coupled logic(DSCL) structure formed with two dynamic-loading master-slav...This paper presents the design and analysis of a high speed broadband divide-by-2 frequency divider. The proposed divider is a dynamic source-coupled logic(DSCL) structure formed with two dynamic-loading master-slave D latches,which enables high frequency operation and low power consumption.This divider exhibits a wide locking range from 7-27 GHz and the minimum power consumption is only 1.22 mW from a 1.2 V supply.The input sensitivity is as low as -25.4 dBm across the operating frequency range.This chip occupies 685×430μm^2 area with two on-chip spiral inductors in 90 nm CMOS process.展开更多
A low-power frequency synthesizer for GPS/Galileo L1/E1 band receivers implemented in a 0.18μm CMOS process is introduced.By adding clock-controlled transistors at latch outputs to reduce the time constant at sensing...A low-power frequency synthesizer for GPS/Galileo L1/E1 band receivers implemented in a 0.18μm CMOS process is introduced.By adding clock-controlled transistors at latch outputs to reduce the time constant at sensing time,the working frequency of the high-speed source-coupled logic prescaler supplying quadrature local oscillator signals has been increased,compared with traditional prescalers.Measurement results show that this synthesizer achieves an in-band phase noise of-87 dBc/Hz at 15 kHz offset,with spurs less than-65 dBc.The whole synthesizer consumes 6 mA in the case of a 1.8 V supply,and its core area is 0.6 mm;.展开更多
A fully integrated 2n/2n+1 dual-modulus divider in GHz frequency range is presented. The improved structure can make all separated logic gates embed into correlative D flip-flops completely. In this way, the complex ...A fully integrated 2n/2n+1 dual-modulus divider in GHz frequency range is presented. The improved structure can make all separated logic gates embed into correlative D flip-flops completely. In this way, the complex logic functions can be performed with a minimum number of devices and with maximum speed, so that lower power consumption and faster speed are obtained. In addition, the low-voltage bandgap reference needed by the frequency divider is specifically designed to provide a 1.0 V output. According to the design demand, the circuit is fabricated in 0.18 μm standard CMOS process, and the measured results show that its operating frequency range is 1.1- 2.5 GHz. The dual-modulus divider dissipates 1.1 mA from a 1.8 V power supply. The temperature coefficient of the reference voltage circuit is 8.3 ppm/℃ when the temperature varies from -40 to + 125 ℃. By comparison, the dual-modulus divide designed in this paper can possess better performance and flexibility.展开更多
基金Supported by Beijing Institute of Technology Science Foundation(3050012211106)
文摘In order to improve the performance of arithmetic very large-scale integration (VLSI) sys- tem, a novel structure of quaternary logic gates is proposed based on multiple-valued current mode (MVCM) by using dynamic source-coupled logic (SCL). Its key components, the comparator and the output generator are both based on differential-pair circuit (DPC), and the latter is constructed by using the structure of DPC trees. The pre-charge evaluates logic style makes a steady current flow cut off, thereby greatly saving the power dissipation. The combination of multiple-valued source- coupled logic and differential-pair circuit makes it lower power consumption and more compact. The performance is evaluated by HSPICE simulation with 0.18 ~m CMOS technology. The power dissipa- tion, transistor numbers and delay are superior to corresponding binary CMOS implementation. Mul- tiple-valued logic will be the potential solution for the high performance arithmetic VLSI system in the future.
文摘This paper presents a novel approach to design robust Source Coupled Logic (SCL) for implementing ultra low power circuits. In this paper, we propose two different source coupled logic structures and analyze the performance of these structures with STSCL (Sub-threshold SCL). The first design under consideration is DTPMOS as load device which analyses the performance of Dynamic Threshold SCL (DTSCL) Logic with previous source coupled logic for ultra low power operation. DTSCL circuits exhibit a better power-delay Performance compared with the STSCL Logic. It can be seen that the proposed circuit provides 56% reduction in power delay product. The second design under consideration uses basic current mirror active load device to provide required voltage swing. Current mirror source coupled logic (CMSCL) can be used for high speed operation. The advantage of this design is that it provides 54% reduction in power delay product over conventional STSCL. The main drawback of this design is that it provides a higher power dissipation compared to other source coupled logic structures. The proposed circuit provides lower sensitivity to temperature and power supply variation, with a superior control over power dissipation. Measurements of test structures simulated in 0.18 μm CMOS technology shows that the proposed DTSCL logic concept can be utilized successfully for bias currents as low as 1 pA. Measurements show that existing standard cell libraries offer a good solution for ultra low power SCL circuits. Cadence Virtuoso schematic editor and Spectre Simulation tools have been used.
文摘采用0.35μm CM O S工艺设计了用于光纤传输系统的低功耗16∶1复接器,实现了将16路155.52M b/s数据复接成一路2.5G b/s的数据输出的功能。该复接器以混合结构形式实现:低速部分采用串行结构,高速部分采用树型结构。具体电路由锁存器、选择器及分频器组成,以CM O S逻辑和源极耦合逻辑(SCL)实现。用Sm art SP ICE软件进行仿真的结果显示:在3.3V供电时,整体电路的复接输出最高工作速度可达3.5G b/s,功耗小于300mW。
文摘A high-speed dual-modulus divide-by-32/33 prescaler has been developed using 0.25 μm CMOS technology. The source-coupled logic (SCL) structure is used to reduce the switching noise and to ameliorate the power-speed tradeoff. The proposed prescaler can operate at high frequency with a low-power consumption. Based on the 2.5 V, 0.25 μm CMOS model, simulation results indicate that the maximum input frequency of the prescaler is up to 3.2 GHz. Running at 2.5 V, the circuit consumes only 4.6 mA at an input frequency 2.5 GHz.
基金supported by the National Basic Research Program of China(No.2010CB327404)the National Natural Science Foundation of China(No.60901012)
文摘This paper presents the design and analysis of a high speed broadband divide-by-2 frequency divider. The proposed divider is a dynamic source-coupled logic(DSCL) structure formed with two dynamic-loading master-slave D latches,which enables high frequency operation and low power consumption.This divider exhibits a wide locking range from 7-27 GHz and the minimum power consumption is only 1.22 mW from a 1.2 V supply.The input sensitivity is as low as -25.4 dBm across the operating frequency range.This chip occupies 685×430μm^2 area with two on-chip spiral inductors in 90 nm CMOS process.
基金Project supported by the National Municipal Sci-Tech Project of China(No.2009ZX01031-002-008)the National High Technology Research and Development Program of China(No.2007AA12Z344).
文摘A low-power frequency synthesizer for GPS/Galileo L1/E1 band receivers implemented in a 0.18μm CMOS process is introduced.By adding clock-controlled transistors at latch outputs to reduce the time constant at sensing time,the working frequency of the high-speed source-coupled logic prescaler supplying quadrature local oscillator signals has been increased,compared with traditional prescalers.Measurement results show that this synthesizer achieves an in-band phase noise of-87 dBc/Hz at 15 kHz offset,with spurs less than-65 dBc.The whole synthesizer consumes 6 mA in the case of a 1.8 V supply,and its core area is 0.6 mm;.
基金supported by the Open Program of National Short-wave Communication Engineering Technology Research Centre(No.HF2013002)
文摘A fully integrated 2n/2n+1 dual-modulus divider in GHz frequency range is presented. The improved structure can make all separated logic gates embed into correlative D flip-flops completely. In this way, the complex logic functions can be performed with a minimum number of devices and with maximum speed, so that lower power consumption and faster speed are obtained. In addition, the low-voltage bandgap reference needed by the frequency divider is specifically designed to provide a 1.0 V output. According to the design demand, the circuit is fabricated in 0.18 μm standard CMOS process, and the measured results show that its operating frequency range is 1.1- 2.5 GHz. The dual-modulus divider dissipates 1.1 mA from a 1.8 V power supply. The temperature coefficient of the reference voltage circuit is 8.3 ppm/℃ when the temperature varies from -40 to + 125 ℃. By comparison, the dual-modulus divide designed in this paper can possess better performance and flexibility.
