Standby Leakage Power Reduction Technique for Nanoscale CMOS VLSI Systems

In this paper, a novel low-power design technique is proposed to minimize the standby leakage power in nanoscale CMOS very large scale integration (VLSI) systems by generating the adaptive optimal reverse body-bias voltage. The adaptive optimal body-bias voltage is generated from the proposed leakage monitoring circuit, which compares the subthreshold current (ISUB) and the band-to-band tunneling (BTBT) current (IBTBT). The proposed circuit was simulated in HSPICE using 32-nm bulk CMOS technology and evaluated using ISCAS85 benchmark circuits at different operating temperatures (ranging from 25°C to 100°C). Analysis of the results shows a maximum of 551 and 1491 times leakage power reduction at 25°C and 100°C, respectively, on a circuit with 546 gates. The proposed approach demonstrates that the optimal body bias reduces a considerable amount of standby leakage power dissipation in nanoscale CMOS integrated circuits. In this approach, the temperature and supply voltage variations are compensated by the proposed feedback loop

Fully Integrated on-Chip Switched DC–DC Converter for Battery-Powered Mixed-Signal SoCs

This paper presents a fully integrated on-chip switched-capacitor (SC) DC–DC converter that supports a programmable regulated power supply ranging from 2.6 to 3.2 V out of a 5 V input supply. The proposed 4-to-3 step-down topology utilizes two conventional 2-to-1 step-down topologies; each of them (2-to-1_up and 2-to-1_dw) has a different flying capacitance to maximize the load current driving capability while minimizing the bottom-plate capacitance loss. The control circuits use a low power supply provided by a small internal low-drop output (LDO) connected to the internal load voltage (VL_dw) from the 2-to-1_dw, and low swing level-shifted gate-driving signals are generated using the internal load voltage (VL_dw). Therefore, the proposed implementation reduces control circuit and switching power consumptions. The programmable power supply voltage is regulated by means of a pulse frequency modulation (PFM) technique with the compensated two-stage operational transconductance amplifier (OTA) and the current-starved voltage controlled oscillator (VCO) to maintain high efficiency over a wide range of load currents. The proposed on-chip SC DC–DC converter is designed and simulated using high-voltage 0.35 μm bipolar, complementary metal-oxide-semiconductor (CMOS) and DMOS (BCDMOS) technology. It achieves a peak efficiency of 74% when delivering an 8 mA load current at a 3.2 V supply voltage level, and it provides a maximum output power of 48 mW (IL = 15 mA at VL_up = 3.2 V) at 70.5% efficiency. The proposed on-chip SC voltage regulator shows better efficiency than the ideal linear regulator over a wide range of output power, from 2.6 mW to 48 mW. The 18-phase interleaving technique enables the worst-case output voltage ripple to be less than 5.77% of the load voltage

A Novel Technique to Minimize Standby Leakage Power in Nanoscale CMOS VLSI

This paper proposes a novel approach to minimize leakage currents in CMOS circuits during the off-state (or standby mode, sleep mode) by applying the optimal reverse body bias to the substrate (body or bulk) to increase the threshold voltage of transistors. The optimal bias point is determined by comparing the sub-threshold current (ISUB) and band-to-band current (IBTBT) simultaneously. The proposed circuit was simulated in HSPICE using 32nm bulk CMOS technology and evaluated using ISCAS85 benchmark circuits at different operating temperature (ranging from 25°C to 100°C). Analysis of the results shows a maximum of 551 and 1491 times leakage power reduction at 25°C and 100°C on a circuit with 546 gates. The proposed approach demonstrates that the optimal body bias reduces considerable amount of the leakage power in the nanoscale CMOS integrated circuits. In this approach, the temperature and supply voltage variations are compensated by the proposed feedback loop

Offset Voltage Analysis of Dynamic Latched Comparator

The offset voltage of the dynamic latched comparator is analyzed in detail, and the dynamic latched comparator design is optimized for the minimal offset voltage based on the analysis in this paper. As a result, 1-sigma offset voltage was reduced from 12.5mV to 6.5mV at the cost of 9% increase of the power dissipation (152μW from 136μW). Using a digitally controlled capacitive offset calibration technique, the offset voltage of the comparator is further reduced from 6.50mV to 1.10mV at 1-sigma at the operating clock frequency of 3 GHz and it consumes 54μW/GHz after the calibration

Fully Integrated on-Chip Switched DC–DC Converter for Battery-Powered Mixed-Signal SoCs

This paper presents a fully integrated on-chip switched-capacitor (SC) DC–DC converter that supports a programmable regulated power supply ranging from 2.6 to 3.2 V out of a 5 V input supply. The proposed 4-to-3 step-down topology utilizes two conventional 2-to-1 step-down topologies; each of them (2-to-1_up and 2-to-1_dw) has a different flying capacitance to maximize the load current driving capability while minimizing the bottom-plate capacitance loss. The control circuits use a low power supply provided by a small internal low-drop output (LDO) connected to the internal load voltage (VL_dw) from the 2-to-1_dw, and low swing level-shifted gate-driving signals are generated using the internal load voltage (VL_dw). Therefore, the proposed implementation reduces control circuit and switching power consumptions. The programmable power supply voltage is regulated by means of a pulse frequency modulation (PFM) technique with the compensated two-stage operational transconductance amplifier (OTA) and the current-starved voltage controlled oscillator (VCO) to maintain high efficiency over a wide range of load currents. The proposed on-chip SC DC–DC converter is designed and simulated using high-voltage 0.35 μm bipolar, complementary metal-oxide-semiconductor (CMOS) and DMOS (BCDMOS) technology. It achieves a peak efficiency of 74% when delivering an 8 mA load current at a 3.2 V supply voltage level, and it provides a maximum output power of 48 mW (IL = 15 mA at VL_up = 3.2 V) at 70.5% efficiency. The proposed on-chip SC voltage regulator shows better efficiency than the ideal linear regulator over a wide range of output power, from 2.6 mW to 48 mW. The 18-phase interleaving technique enables the worst-case output voltage ripple to be less than 5.77% of the load voltage