Ao Ba scite author profile

This paper presents an ultra-low-power (ULP) fully-integrated Bluetooth Low-Energy(BLE)/IEEE802.15.4/proprietary RF SoC for Internet-of-Things applications. Ubiquitous wireless sensors connected through cellular devices are becoming widely used in everyday life. A ULP RF transceiver [1-3] is one of the most critical components that enables these emerging applications, as it can consume up to 90% of total battery energy. Furthermore, a low-cost radio design with an area-efficient fully integrated RF SoC is an important catalyst for developing such applications. By employing a low-voltage digital-intensive architecture, the presented SoC is fully compliant with BLE and IEEE802.15.4 PHY/Data-link requirements and achieves state-of-the-art power consumption of 3.7mW for RX and 4.4mW for TX. Figure 13.2.1 shows the architecture of the RF SoC. An all-digital TX consists of a sub-mW snapshot-TDC all-digital PLL (ADPLL) [4] and an energy-efficient Class-D PA. A sliding-IF RX is adopted because it does not require a powerhungry LO generation. The PA with partial on-chip impedance matching and the LNA are both single-ended, which reduce external components and simplify the antenna interface design. A multistandard DBB [5] includes all PHY processing and data link for BLE and IEEE802.15.4. In this work the DBB further includes optimized HW/SW register interfaces and HW accelerators for protocol support, and implements an AHB/APB interface to facilitate integration with an ARM Cortex TM -M0 MCU and 128kB SRAM.One of the most challenging parts of the BLE RX mode is to receive the packets with an extremely short 8b preamble, which requires fast automatic gain control (AGC) and carrier-frequency offset (CFO) compensation method. A two-step AGC algorithm performs only coarse gain tuning in the RF parts (i.e., LNA and mixers) during the preamble with 12dB/step, allowing the RX output amplitude to quickly settle within the ADC dynamic range in just a few symbol periods. The fine amplitude tuning is performed in the LPF/PGA during the access code period with 3dB/step. Furthermore, BLE also specifies that the RX should accommodate a "dirty TX" with a large CFO up to ±100kHz (±41ppm). The CFO could be post-compensated in the DBB with a phase rotator, but then the LPF BW needs to be at least 100kHz wider, which compromises the adjacent channel rejection. In this work, a mixed-mode CFO compensation through an ADPLL allows direct compensation in the analog domain without increasing LPF BW. The CFO is first estimated by the DBB based solely on a part of the packet's preamble. The CFO estimation unit employs a 17-tap FIR filter with low latency. The CFO is detected by converting the IQ data to phase difference, and averaging it across preamble symbols. The CFO is then compensated by directly adjusting the fractional-N ADPLL with a frequency resolution of 1kHz. However, PLLs typically have a slow settling in the order of 20μs, which is not fast enough to compensate the CFO within the preamble. Therefore, the 2-point injection technique emp...

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A 0.33 nJ/bit IEEE802.15.6/Proprietary MICS/ISM Wireless Transceiver With Scalable Data Rate for Medical Implantable Applications

Vidojkovic

Kanda

et al. 2015

IEEE J. Biomed. Health Inform.

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This paper presents an ultra-low power wireless transceiver specialized for but not limited to medical implantable applications. It operates at the 402-405-MHz medical implant communication service band, and also supports the 420-450-MHz industrial, scientific, and medical band. Being IEEE 802.15.6 standard compliant with additional proprietary modes, this highly configurable transceiver achieves date rates from 11 kb/s to 4.5 Mb/s, which covers the requirements of conventional implantable applications. The phase-locked loop-based transmitter architecture is adopted to support various modulation schemes with limited power budget. The zero-IF receiver has programmable gain and bandwidth to accommodate different operation modes. Fabricated in 40-nm CMOS technology with 1-V supply, this transceiver only consumes 1.78 mW for transmission and 1.49 mW for reception. The ultra-low power consumption together with the 15.6-compliant performance in term of modulation accuracy, sensitivity, and interference robustness make this transceiver competent for various implantable applications.

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A 1.9nJ/b 2.4GHz multistandard (Bluetooth Low Energy/Zigbee/IEEE802.15.6) transceiver for personal/body-area networks

Liu

Huang

Vidojkovic

et al. 2013

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Ao Ba

9.8 An 860μW 2.1-to-2.7GHz all-digital PLL-based frequency modulator with a DTC-assisted snapshot TDC for WPAN (Bluetooth Smart and ZigBee) applications

A 915 MHz, Ultra-Low Power 2-Tone Transceiver With Enhanced Interference Resilience

13.2 A 3.7mW-RX 4.4mW-TX fully integrated Bluetooth Low-Energy/IEEE802.15.4/proprietary SoC with an ADPLL-based fast frequency offset compensation in 40nm CMOS

A 0.33 nJ/bit IEEE802.15.6/Proprietary MICS/ISM Wireless Transceiver With Scalable Data Rate for Medical Implantable Applications

A 1.9nJ/b 2.4GHz multistandard (Bluetooth Low Energy/Zigbee/IEEE802.15.6) transceiver for personal/body-area networks

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Ao Ba

9.8 An 860&#x03BC;W 2.1-to-2.7GHz all-digital PLL-based frequency modulator with a DTC-assisted snapshot TDC for WPAN (Bluetooth Smart and ZigBee) applications

A 915 MHz, Ultra-Low Power 2-Tone Transceiver With Enhanced Interference Resilience

13.2 A 3.7mW-RX 4.4mW-TX fully integrated Bluetooth Low-Energy/IEEE802.15.4/proprietary SoC with an ADPLL-based fast frequency offset compensation in 40nm CMOS

A 0.33 nJ/bit IEEE802.15.6/Proprietary MICS/ISM Wireless Transceiver With Scalable Data Rate for Medical Implantable Applications

A 1.9nJ/b 2.4GHz multistandard (Bluetooth Low Energy/Zigbee/IEEE802.15.6) transceiver for personal/body-area networks

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Product

Resources

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9.8 An 860μW 2.1-to-2.7GHz all-digital PLL-based frequency modulator with a DTC-assisted snapshot TDC for WPAN (Bluetooth Smart and ZigBee) applications