Yang Liu

Bio: Yang Liu is an academic researcher from Southern University of Science and Technology. The author has contributed to research in topics: Voltage reference & Subthreshold conduction. The author has an hindex of 5, co-authored 8 publications receiving 105 citations.

An Ultralow Power Subthreshold CMOS Voltage Reference Without Requiring Resistors or BJTs

Abstract: This brief presents a novel ultralow power CMOS voltage reference (CVR) with only 4.6-nW power consumption. In the proposed CVR circuit, the proportional-to-absolute-temperature voltage is generated by feeding the leakage current of a zero- $V_{\mathrm {gs}}$ nMOS transistor to two diode-connected nMOS transistors in series, both of which are in subthreshold region; while the complementary-to-absolute-temperature voltage is created by using the body diodes of another nMOS transistor. Consequently, low-power operation can be achieved without requiring resistors or bipolar junction transistors, leading to small chip area consumption. The proposed CVR circuit is fabricated in a standard 0.18- $\mu \text{m}$ CMOS process. Measurement results show that the prototype design is capable of providing a 755 mV typical reference voltage with 34 ppm/°C from −15 °C to 140 °C. Moreover, the typical power consumption is only 4.6 nW at room temperature and the active area is only 0.0598 mm2.

A 0.4-V Wide Temperature Range All-MOSFET Subthreshold Voltage Reference With 0.027%/V Line Sensitivity

Abstract: This brief presents a CMOS voltage reference for ultra-low-power applications, such as in implementable medical devices and energy harvesting-based wireless sensor nodes. In these applications, excellent capabilities to reject interference from power sources and work in low voltage to extend survival periods are critical for the voltage references. A transistor size-ratio determined current generator with high process and voltage independence is implemented by two same-threshold-voltage NMOS transistors, hence obtaining the precise reference voltage with an active load. The proposed circuit is fabricated in a standard 0.18- ${\mu }\text{m}$ CMOS process. Measurement results show that the prototype design provides a 210-mV reference with only 0.027% line sensitivity with a supply voltage from 1.8 V down to 0.4 V. The power supply ripple rejection at 10 Hz, 1 KHz, and 1 MHz is −59, 47, and 53 dB, respectively. The temperature coefficient is 82 ppm/°C in the temperature range from −40°C to +140 °C. Furthermore, the power consumption is only 9.6 nW at room temperature and the active area is 0.021 mm2.

A 0.9-V 33.7-ppm/°C 85-nW Sub-Bandgap Voltage Reference Consisting of Subthreshold MOSFETs and Single BJT

Abstract: A low temperature coefficient (TC) and high power supply ripple rejection (PSRR) CMOS sub-bandgap voltage reference (sub-BGR) circuit using subthreshold MOS transistors and a single BJT is presented in this brief. The proposed sub-BGR consists of a novel complementary-to-absolute-temperature (CTAT) voltage generator based on a scaled emitter-base voltage of a BJT, and an improved proportional-to-absolute-temperature (PTAT) voltage generator based on stacking of $\Delta V_{\mathbf {GS}}$ of sub- $V_{\mathbf {TH}}$ MOSFETs. As the CTAT circuit achieves a reduced absolute value of the negative TC, the PTAT circuit achieves reduced power consumption without consuming a large chip area. The proposed sub-BGR circuit is implemented in a standard 0.18- $\mu \text{m}$ CMOS process. Measured results show that the sub-BGR circuit can run with a supply voltage down to 0.9 V while the power consumption is only 85 nW. An average TC of 33.7 ppm/°C and a PSRR of better than −40 dB over the full frequency range are achieved.

A Low-Power High-PSRR CMOS Voltage Reference with Active-Feedback Frequency Compensation for IoT Applications

Abstract: A low-power CMOS voltage reference with active-feedback frequency compensation is proposed for power-constrained IoT applications whereby power supply ripple rejection (PSRR) performance is critical for the survival of the devices. The proposed voltage reference consists of MOS transistors operating in the sub-threshold region to allow for low-voltage and low-power operations. An active-feedback frequency compensation technique has been used to make the loop stable and improve the PSRR with a very small compensation capacitor while allowing a relatively large output capacitor. The circuit is fabricated in a standard 0.18-μm CMOS process. The measured power consumption is 22nW at 0.7V power supply. The measured temperature coefficient (TC) is 38ppm/°C in a range from −40 to +110°C, and the line regulation is 200μV/V in a supply voltage range of 0.7∼2V. The measured PSRR at 10 Hz, 1 kHz, and 100 kHz is −64dB, −56dB, and −52dB, respectively. The active chip area is 0.04mm2.

Design Of Analog Cmos Integrated Circuits

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A 0.7-V 28-nW CMOS Subthreshold Voltage and Current Reference in One Simple Circuit

Abstract: This paper presents a low-power and high-precision voltage and current reference (VCR) in one simple circuit. The voltage reference is derived from the threshold voltage difference between an I/O (i.e., 3.3-V NMOS) and standard (i.e., 1.8-V NMOS) transistors with temperature-independent bias current, and the current reference is the voltage reference divided by a temperature-insensitive resistor. The resistor is made up by series connection of a proportional-to-absolute-temperature (PTAT) NWELL resistor and a complementary-to-absolute-temperature (CTAT) high-resistance poly resistor in series. Implemented in a standard 0.18- $\mu \text{m}$ CMOS process, the proposed VCR circuit takes an active area of only 0.055 mm2. The measured voltage and current references ( $\text{V}_{\mathrm {ref}}$ and $\text{I}_{\mathrm {ref}}$ ) at room temperature are 368 mV and 9.77 nA, respectively. The measured average temperature coefficient (TC) of $\text{V}_{\mathrm {ref}}$ and $\text{I}_{\mathrm {ref}}$ are 43.1 ppm/°C and 149.8 ppm/°C over a temperature range of −40~125°C with one-time trimming and the variation coefficients are 0.35% and 1.6%, respectively. The measured voltage and current line sensitivities are 0.027%/V and 0.6%/V, respectively. The minimum supply voltage is 0.7 V with a total power consumption of 28 nW. The measured power supply ripple rejection (PSRR) of $\text{V}_{\mathrm {ref}}$ is −65 dB @DC and −39.4 dB at frequencies higher than 1 Hz.

Re-Thinking Analog Integrated Circuits in Digital Terms: A New Design Concept for the IoT Era

Abstract: A steady trend towards the design of mostly-digital and digital-friendly analog circuits, suitable to integration in mainstream nanoscale CMOS by a highly automated design flow, has been observed in the last years to address the requirements of the emerging Internet of Things (IoT) applications. In this context, this tutorial brief presents an overview of concepts and design methodologies that emerged in the last decade, aimed to the implementation of analog circuits like Operational Transconductance Amplifiers, Voltage References and Data Converters by digital circuits. The current design challenges and application scenarios as well as the future perspectives and opportunities in the field of digital-based analog processing are finally discussed.

An Ultralow Power Subthreshold CMOS Voltage Reference Without Requiring Resistors or BJTs

Abstract: This brief presents a novel ultralow power CMOS voltage reference (CVR) with only 4.6-nW power consumption. In the proposed CVR circuit, the proportional-to-absolute-temperature voltage is generated by feeding the leakage current of a zero- $V_{\mathrm {gs}}$ nMOS transistor to two diode-connected nMOS transistors in series, both of which are in subthreshold region; while the complementary-to-absolute-temperature voltage is created by using the body diodes of another nMOS transistor. Consequently, low-power operation can be achieved without requiring resistors or bipolar junction transistors, leading to small chip area consumption. The proposed CVR circuit is fabricated in a standard 0.18- $\mu \text{m}$ CMOS process. Measurement results show that the prototype design is capable of providing a 755 mV typical reference voltage with 34 ppm/°C from −15 °C to 140 °C. Moreover, the typical power consumption is only 4.6 nW at room temperature and the active area is only 0.0598 mm2.

A 0.4-V Wide Temperature Range All-MOSFET Subthreshold Voltage Reference With 0.027%/V Line Sensitivity

Abstract: This brief presents a CMOS voltage reference for ultra-low-power applications, such as in implementable medical devices and energy harvesting-based wireless sensor nodes. In these applications, excellent capabilities to reject interference from power sources and work in low voltage to extend survival periods are critical for the voltage references. A transistor size-ratio determined current generator with high process and voltage independence is implemented by two same-threshold-voltage NMOS transistors, hence obtaining the precise reference voltage with an active load. The proposed circuit is fabricated in a standard 0.18- ${\mu }\text{m}$ CMOS process. Measurement results show that the prototype design provides a 210-mV reference with only 0.027% line sensitivity with a supply voltage from 1.8 V down to 0.4 V. The power supply ripple rejection at 10 Hz, 1 KHz, and 1 MHz is −59, 47, and 53 dB, respectively. The temperature coefficient is 82 ppm/°C in the temperature range from −40°C to +140 °C. Furthermore, the power consumption is only 9.6 nW at room temperature and the active area is 0.021 mm2.