An ultra-low-power 9.8GHz crystal-less UWB transceiver with digital baseband integrated in 0.18&amp;#x00B5;m BiCMOS

Brown, Jonathan K.; Huang, Kuo-Ken; Ansari, Elnaz; Rogel, Ryan R.; Lee, Yoonmyung; Wentzloff, David D.

doi:10.1109/isscc.2013.6487806

Cited by 9 publications

(7 citation statements)

References 3 publications

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“…at 2.5 GHz impulse generation, which can be performed by utilizing relaxed requirement of spectrum mask and ACPR: the output signal is just required to meet the restriction of Japanese extremely low power radio station, and thus the TX can be simplified for reducing power. The duty cycling operation can save power consumption P [2], which can be expressed by…”

Section: Improvement Of Power Consumption and Energy Per Bitmentioning

confidence: 99%

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A 2.3 pJ/bit frequency-stable impulse OOK transmitter powered directly by an RF energy harvesting circuit with −19.5 dBm sensitivity

Ito

Masui

Momiyama

et al. 2014

2014 IEEE Radio Frequency Integrated Circuits Symposium

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The proposed 2.5-GHz-band impulse transmitter technology realizes frequency-stable impulse generation against PVT variation and superior energy-per-bit operation, and it can be powered directly from a − 19.5-dBm-sensitivity RF energy harvesting circuit without any regulators that are generally essential to power RF circuits. The transmitter occupies 0.38 mm 2 in a 65nm CMOS technology. The maximum frequency difference among measured output return-loss peak of 9 chips with 3 different process corners under 0.5 V supply is about 50 MHz without any frequency calibration. Our prototype achieves 1 Mb/s signal transmission under 2.3 µW power consumption from 0.5 V supply thanks to pulse-level duty cycling operation of maximally digital architecture.Index Terms -Impulse ultra-wideband radio, Ultra low power RF, RF energy harvesting I. INTRODUCTIONThe impulse ultra-wideband (I-UWB) RFID technique has been leading short-range wireless communication technology toward internet-of-things application due to its abilities of high throughput, low power consumption and so on. While previous works have realized complicating I-UWB transceivers [1], [2], one of the next significant challenges for the short-range tag technology is how to minimize the cost for expanding its application especially toward low-end and large-volume markets.This paper proposes 2.5-GHz-band impulse transmitter (TX) technology which can contribute to save a tag cost in term of power supply and form factor. Features of our approaches are (1) frequency-stable impulse generation technique, and (2) pulse-level duty cycling with suppressed leakage by maximally digital architecture. The proposed technique can generate an impulse signal with stable RF carrier-frequency against PVT variation, which enables to remove supply-voltage conditioning circuits such as regulators and to be powered by a proposed RF energy harvesting circuit (RF-EH) directly. This paper also addresses ideas to achieve both ultra-low power consumption and superior energy per bit concurrently.

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Section: Improvement Of Power Consumption and Energy Per Bitmentioning

confidence: 99%

“…While previous works have realized complicating I-UWB transceivers [1], [2], one of the next significant challenges for the short-range tag technology is how to minimize the cost for expanding its application especially toward low-end and large-volume markets.…”

Section: Introductionmentioning

confidence: 99%

A 2.3 pJ/bit frequency-stable impulse OOK transmitter powered directly by an RF energy harvesting circuit with −19.5 dBm sensitivity

Ito

Masui

Momiyama

et al. 2014

2014 IEEE Radio Frequency Integrated Circuits Symposium

View full text Add to dashboard Cite

show abstract

“…The research community has pushed the envelope further, exploring an array of “microscale”—ultra-low power and millimeter-sized—building blocks including processors [8, 37], radios [4, 7, 26], other long-range communication technologies [6], ADCs [28], regulators [33], timers [15, 16], and sensing frontends [9, 17]. However, few of these components have been integrated into complete systems.…”

Section: Introductionmentioning

confidence: 99%

MBus

Pannuto

Lee

Kuo

et al. 2015

Proceedings of the 42nd Annual International Symposium on Computer Architecture

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As we show in this paper, I/O has become the limiting factor in scaling down size and power toward the goal of invisible computing. Achieving this goal will require composing optimized and specialized—yet reusable—components with an interconnect that permits tiny, ultra-low power systems. In contrast to today’s interconnects which are limited by power-hungry pull-ups or high-overhead chip-select lines, our approach provides a superset of common bus features but at lower power, with fixed area and pin count, using fully synthesizable logic, and with surprisingly low protocol overhead. We present MBus, a new 4-pin, 22.6 pJ/bit/chip chip-to-chip interconnect made of two “shoot-through” rings. MBus facilitates ultra-low power system operation by implementing automatic power-gating of each chip in the system, easing the integration of active, inactive, and activating circuits on a single die. In addition, we introduce a new bus primitive: power oblivious communication, which guarantees message reception regardless of the recipient’s power state when a message is sent. This disentangles power management from communication, greatly simplifying the creation of viable, modular, and heterogeneous systems that operate on the order of nanowatts. To evaluate the viability, power, performance, overhead, and scalability of our design, we build both hardware and software implementations of MBus and show its seamless operation across two FPGAs and twelve custom chips from three different semiconductor processes. A three-chip, 2.2 mm3 MBus system draws 8 nW of total system standby power and uses only 22.6 pJ/bit/chip for communication. This is the lowest power for any system bus with MBus’s feature set.

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“…The impulse radio is the potential candidate to realize both ultra-low power communication and localization with modest accuracy. The previous works have achieved impulse radio circuit with power dissipation of tens of microwatts [1,2]. Localization technology based on an received signal strength indicator (RSSI) in ultra-wideband (UWB) networks has been studied [3], which can be lowpower localization solution because time synchronization and clock precision can be considerably relaxed as compared to time of arrival (TOA) or time difference of arrival (TDOA) technique.…”

Section: Introductionmentioning

confidence: 99%

An ultra-low-power RF transceiver with a 1.5-pJ/bit maximally-digital impulse-transmitter and an 89.5-μW super-regenerative RSSI

Ito

Yoneda

Ibe

et al. 2014

2014 IEEE Asian Solid-State Circuits Conference (A-Sscc)

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This paper proposes an RF transceiver with a maximally-digital impulse transmitter (I-TX) and a superregenerative received-signal-strength-indicator (RSSI) circuit for wireless sensor network (WSN) application. Our I-TX enables strict bit-level duty cycling operation to achieve both ultralow power consumption and superior energy-per-bit in kb/s to Mb/s range. The proposed RSSI for low-power localization and low-rate downlink measures input power by exploiting the phenomenon that the oscillation start-up time logarithmically accelerates as input power increases. The I-TX fabricated in a 65nm CMOS achieves energy-per-bit of 1.5 pJ/bit at 10 Mb/s which is better than previous works. The proposed RSSI with −85 dBm sensitivity consumes 89.5 μW with modest dynamic range and linearity.

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An ultra-low-power 9.8GHz crystal-less UWB transceiver with digital baseband integrated in 0.18µm BiCMOS

Cited by 9 publications

References 3 publications

A 2.3 pJ/bit frequency-stable impulse OOK transmitter powered directly by an RF energy harvesting circuit with −19.5 dBm sensitivity

A 2.3 pJ/bit frequency-stable impulse OOK transmitter powered directly by an RF energy harvesting circuit with −19.5 dBm sensitivity

MBus

An ultra-low-power RF transceiver with a 1.5-pJ/bit maximally-digital impulse-transmitter and an 89.5-μW super-regenerative RSSI

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An ultra-low-power 9.8GHz crystal-less UWB transceiver with digital baseband integrated in 0.18&#x00B5;m BiCMOS

Cited by 9 publications

References 3 publications

A 2.3 pJ/bit frequency-stable impulse OOK transmitter powered directly by an RF energy harvesting circuit with &#x2212;19.5 dBm sensitivity

A 2.3 pJ/bit frequency-stable impulse OOK transmitter powered directly by an RF energy harvesting circuit with &#x2212;19.5 dBm sensitivity

MBus

An ultra-low-power RF transceiver with a 1.5-pJ/bit maximally-digital impulse-transmitter and an 89.5-&#x03BC;W super-regenerative RSSI

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Product

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About

An ultra-low-power 9.8GHz crystal-less UWB transceiver with digital baseband integrated in 0.18µm BiCMOS

A 2.3 pJ/bit frequency-stable impulse OOK transmitter powered directly by an RF energy harvesting circuit with −19.5 dBm sensitivity

A 2.3 pJ/bit frequency-stable impulse OOK transmitter powered directly by an RF energy harvesting circuit with −19.5 dBm sensitivity

An ultra-low-power RF transceiver with a 1.5-pJ/bit maximally-digital impulse-transmitter and an 89.5-μW super-regenerative RSSI