Self-Powered Photovoltaic Bluetooth® Low Energy Temperature Sensor Node

Elizalde, Jorge; Cruces, Cristina; Sandoval, Michael Stiven; Eguiluz, Xabier; Val, Iñaki

doi:10.1109/access.2021.3103388

Cited by 2 publications

(2 citation statements)

References 23 publications

(27 reference statements)

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“…However, it is a real problem in complex industrial environments or in case of long-range transmission. Some articles present the restart after a phase without energy recovery [27], and to avoid the cold start, a preload is sometimes used during laboratory tests [28]. But very few papers address the cold start issue [29] [30].…”

Section: Battery Free Systemmentioning

confidence: 99%

Battery-Free Power Supply for Wireless Sensor Combining Photovoltaic Cells and Supercapacitors

Boitier¹,

Estibals²,

Huet³

et al. 2023

EPE

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This article exhibits the sizing, modelling, and characterization of a power supply (output 3.3 V, 200 mA max, 11 days full autonomy) dedicated to powering a wireless sensor node without a battery but usable as simply as with a battery. This system is modular for various light levels (indoor and outdoor). It is easily integrable into a sensor node, using only commercial circuits. The choices of the photovoltaic surface (amorphous silicon, η 5%, 35 cm 2 ) and of the supercapacitors value (2x 25F, 2.7 V) are explained for permanent operation, considering the solar potential and the consumption. An original part of the paper is devoted to the issue of the startup, in which we demonstrate that after a particular preload, once installed, the device can start on request at the desired time (within 15 days) using as a trigger any light source, such as the LED of a mobile phone.

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Section: Battery Free Systemmentioning

confidence: 99%

Battery-Free Power Supply for Wireless Sensor Combining Photovoltaic Cells and Supercapacitors

Boitier¹,

Estibals²,

Huet³

et al. 2023

EPE

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show abstract

“…In recent years, various on-chip temperature sensing methods have been proposed, as well as low-power applications that use them. [1][2][3][4] Bipolar junction transistor-based methods utilize the temperature dependencies seen in the base-emitter voltage of a BJT. [5][6][7][8][9][10][11][12] Sensors that utilize this property are known to have very high sensing accuracy over a wide temperature range.…”

Section: Introductionmentioning

confidence: 99%

Wide-range and low supply dependency MOSFET-based temperature sensor utilizing statistical properties of scaled MOSFETs

Ota

Islam

Hisakado

et al. 2023

Jpn. J. Appl. Phys.

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We present a MOSFET-based temperature sensing method capable of high-accuracy temperature estimation across a wide temperature range while having a low supply voltage dependency. Existing MOSFET-based sensors, while capable of low-power operation, suffer from low sensing accuracy and a narrow sensing range. The proposed method utilizes per-MOSFET parameter variations seen in scaled CMOS processes. By measuring a statistical parameter of sub-threshold drain currents, we can extract a complimentary temperature value. To prove the feasibility of our method, we measured six chips fabricated with a commercial 65nm process. The proposed method achieves a sensing accuracy of −0.54/+0.43 ℃ within a temperature range of −20 to 120 ℃ at a supply voltage of 1.2 V. In addition, the proposed method has a worst-case supply dependency of 3.7 ℃/V at 20 ℃.

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Self-Powered Photovoltaic Bluetooth® Low Energy Temperature Sensor Node

Cited by 2 publications

References 23 publications

Battery-Free Power Supply for Wireless Sensor Combining Photovoltaic Cells and Supercapacitors

Battery-Free Power Supply for Wireless Sensor Combining Photovoltaic Cells and Supercapacitors

Wide-range and low supply dependency MOSFET-based temperature sensor utilizing statistical properties of scaled MOSFETs

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