A 6.6-<i>μ</i>W Wheatstone-Bridge Temperature Sensor for Biomedical Applications

Pan, Sining; Makinwa, Kofi A. A.

doi:10.1109/lssc.2020.3019078

Cited by 13 publications

(3 citation statements)

References 9 publications

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“…Power Management [25,66] Protocol Framework [64] Digital Signal Processor Analysis of Energy Harvesting Model [45] memory technology in IoT applications. The on-chip 2MB STT-MRAM (replaces lash) is currently utilized as irmware for the startup program in the Ambiq Apollo4 microprocessor [1].…”

Section: Charging Managementmentioning

confidence: 99%

“…The energy harvesting technology can dramatically extend the lifetime of the system and has attracted much attention for IoT devices. For example, the implantable medical application can work for up to 10 years by collecting human-body energy into electricity through biomedical sensors [45]. Since the harvested energy is usually unstable and diicult to utilize efectively, the system with the energy harvesting technology may sufer unpredictable frequent energy failures and intermittently luctuating energy conditions.…”

Section: Introductionmentioning

confidence: 99%

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Experimental Demonstration of STT-MRAM-based Nonvolatile Instantly On/Off System for IoT Applications: Case Studies

Wang

Zhou

et al. 2023

ACM Trans. Embed. Comput. Syst.

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Energy consumption has been a big challenge for electronic devices, particularly, for the battery-powered Internet of Things (IoT) equipment. To address such a challenge, on one hand, low-power electronic design methodologies and novel power management techniques have been proposed, such as nonvolatile memories and instantly on/off systems; on the other hand, the energy harvesting technology by collecting signals from human activity or the environment has attracted widespread attention in the IoT area. However, the system with self-powered energy harvesting may suffer frequent energy failures or fluctuating energy conditions, which degrade system reliability and user experience. Therefore, how to make the system under unreliable power inputs operate correctly and efficiently is one of the most critical issues for the energy harvesting technology. In this paper, we built an instantly on/off system based on nonvolatile STT-MRAM for IoT applications, which can instantly power on/off under different conditions of the harvested energy. The system powers on and operates normally when the harvested energy is enough (over the preset threshold); otherwise, the system powers off and stores the operational data back to the nonvolatile STT-MRAM. We described implementations of the hardware/software co-designed architecture (with image acquisition as an example) based on the commercialized 32MB STT-MRAM, and experimentally demonstrated the system functionality and efficiency under five typical energy harvesting scenarios, including radio-frequency (RF), thermal, solar, piezoelectric and WIFI. Our experimental results show that the power consumption and data restore time were reduced by 15.1 \(\% \) and 714 times respectively in comparison with the DRAM-based counterpart.

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Section: Charging Managementmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Experimental Demonstration of STT-MRAM-based Nonvolatile Instantly On/Off System for IoT Applications: Case Studies

Wang

Zhou

et al. 2023

ACM Trans. Embed. Comput. Syst.

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“…Indeed, ON-chip temperature sensors constitute a fundamental block in a wide range of applications [1] as they can be used for realizing precise relative measurements, which require high resolution, or for implementing reliable absolute measurements, which necessitate low inaccuracy. Precise relative temperature measurements are needed in micro-electro-mechanical systems (MEMS) to compensate for the thermal drift of their parameters, which would otherwise determine a degradation in their performance [2], [3], [4], [5], while reliable absolute temperature measurements are required in biomedical applications [6], [7], [8], e.g., for implementing the reference detectors in contactless temperature sensors for the human body [9], and in thermal monitoring of the food and healthcare products cold chain maintenance [10], [11], [12]. Moreover, ON-chip temperature sensors are a fundamental block in microprocessors thermal management, as they enable responsive temperature tracking in order to allow dynamic voltage and frequency scaling (DVFS) and the cooling fans speed regulation [13], [14], [15], as well as in bandgap reference generation [16], [17].…”

Section: Introductionmentioning

confidence: 99%

A MOS-Based Temperature Sensor With Inherent Inaccuracy Reduction Enabled by Time-Domain Operation

Moisello

Ippolito

Bruno

et al. 2023

IEEE Trans. Instrum. Meas.

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This article presents a MOS-based ON-chip temperature sensor system addressing both high-resolution and lowinaccuracy requirement, red while requiring a single temperature calibration point. Hence, the proposed temperature sensor system proves to be a low-cost solution, well addressing the requirements of the spreading market of system-on-chips (SoCs), mobile and wearable devices, and consumer electronics in general. The temperature sensor features a two-phase time-domain architecture, which employs as a sensing element a single NMOS transistor, biased alternatively with different currents, thus allowing achieving an inherent inaccuracy reduction. The proposed sensory system, fabricated in a standard 130-nm CMOS process, comprises, along the sensor core, a switched-capacitor analog interface circuit and a 1-bit second-order sigma-delta ( ) analog-to-digital converter (ADC). The proposed temperatureto-digital converter (TDC), experimentally characterized considering a batch of 16 samples, achieves 40-mK resolution at 20-kHz switching frequency and +0.75/−0.92 • C inaccuracy across the −40 • C-90 • C temperature range after one-point calibration at room temperature, consuming 25.4 µW, including the analog buffer added for testing purposes.

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