An Accurate BJT-Based CMOS Temperature Sensor With Duty-Cycle-Modulated Output

Wang, Guijie; Heidari, Ali; Makinwa, Kofi A. A.; Meijer, G.C.M.

doi:10.1109/tie.2016.2614273

Cited by 48 publications

(29 citation statements)

References 24 publications

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“…In previous TDCs [6]- [9], [14]- [16], different techniques have been used to reduce the effects of spread in the various parameters of (4) and (5). Choosing a small biasing current (I E ) mitigates the effect of r S (i.e., the last terms in (4) and (5)) and its variation.…”

Section: Background and Error Sourcesmentioning

confidence: 99%

“…In order to increase the accuracy of ∆V BE , dynamic element matching (DEM) has been used [6]- [9], [14]- [16] to accurately define p E (first term in (5)). This will improve the accuracy of ∆V BE , provided that β is current independent (i.e., ∆β = 0, in the second term of (5)), or that β This is the author's version of an article that has been published in this journal.…”

Section: Background and Error Sourcesmentioning

confidence: 99%

“…To mitigate such errors, the current mirror ratio p Eb is dynamically matched (DEM1), in the same way as the current mirror ratio p E (DEM2). For the same reasons, a similar approach was recently used in [16]. Furthermore, to ensure that biasing currents are accurately copied from the biasing-circuit to the bipolar-core, the two banks of current mirrors are dynamically swapped (Bank-Swap).…”

Section: B Precision Biasing-circuitmentioning

confidence: 99%

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A BJT-Based Temperature-to-Digital Converter With ±60 mK ( $3~\sigma$ ) Inaccuracy From −55 °C to +125 °C in 0.16-μm CMOS

Yousefzadeh

Shalmany²,

Makinwa

2017

IEEE J. Solid-State Circuits

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This paper presents a precision CMOS temperature-to-digital converter (TDC), which senses the temperature-dependent base-emitter voltage of substrate PNPs. Measurements on 20 samples from one batch show that it achieves an inaccuracy of ±60mK (3σ) from −55 • C to +125 • C, after a single room temperature trim. This state-of-the-art result is mainly due to the extensive use of dynamic error cancellation techniques to generate the PNP's collector currents, thus minimizing the spread in their base-emitter voltages, together with a digital PTAT trim to correct for the spread in the PNP's saturation currents. The effect of process variation on the TDC's inaccuracy was investigated by measuring 80 samples from 3 different batches. With the same calibration parameters, they exhibit a maximum untrimmed inaccuracy of ±2 • C (3σ) from −55 • C to +125 • C. This drops to ±100mK (3σ) after a single point trim. The proposed TDC thus reduces calibration costs by obviating the need for batchspecific calibration parameters, which would otherwise require the multi-point calibration of several samples. The effect of the PNP's current-gain β was also investigated with the help of a novel βdetection circuit. Implemented in 0.16µm CMOS, the TDC occupies 0.16mm 2 and draws 4.6µA from 1.5 to 2V supply voltages. It achieves a resolution FoM of 7.8pJ • C 2 , and a state-of-the-art supply sensitivity of 0.01 • C/V.

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Section: Background and Error Sourcesmentioning

confidence: 99%

Section: Background and Error Sourcesmentioning

confidence: 99%

Section: B Precision Biasing-circuitmentioning

confidence: 99%

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A BJT-Based Temperature-to-Digital Converter With ±60 mK ( $3~\sigma$ ) Inaccuracy From −55 °C to +125 °C in 0.16-μm CMOS

Yousefzadeh

Shalmany²,

Makinwa

2017

IEEE J. Solid-State Circuits

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“…Due to the high-power usage of the processor, it is even challenging to add-on the thermal sensor into the processor [6]. For an on-chip temperature sensors, it must be compatible with the technology available in the process, maintain a small area, has good accuracy with low power consumption over standard process variations and over typical supply voltage variations [1,4,[6][7].…”

Section: Introductionmentioning

confidence: 99%

CMOS based thermal detector for processor

Yang

Jubadi

2020

IJEECS

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<p>This project proposed a design of low power CMOS-based thermal detector which can detect the temperature of processor such as in Central Processing Unit. By re-designing temperature detector circuit using CMOS technology, the reduction in power consumption and area size of the thermal detector can be obtained. In this paper, the design of thermal detector consists of temperature sensing core, amplifier, and Analog to Digital Converter (ADC), respectively. The sensor was designed using 0.13 µm CMOS technology and operates by sensing the temperature of processor and produced a digital output value. The temperature detection range was setup between 0 °C to 80 °C with 10 °C resolution. The temperature detector was capable to show temperature readings in binary value. It consumed an average power of 558.2 µW and a space occupancy of 0.0118 mm².</p>

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“…It was for three decades the active device of choice in the analog design of integrated circuits used in wide applicability in electronics, including computers, televisions, mobile phones, audio amplifiers, industrial control, and radio-frequency (RF) circuits of the wireless systems [1], but today the use of the BJT has declined in favor of the CMOS technology in the design of digital integrated circuits (ICs) [2][3][4]. Due to the low impedance at the base, high transconductance, and output resistance compared to MOS devices, the BJT is characterized as currentcontrolled current source useful to compute nonlinear functions by their logarithm dependence between base-emitter voltage , collector current , and temperature, which recently has led to its integration into the CMOS-based architectures [5][6][7][8]. Currently, the BJT has been shown to be a viable option as transducer in electrochemical sensor, because it has significantly greater sensitivity and signal to noise ratio (SNR) and minor calibration requirements independent of voltages for operation, which implies that optimal measurements can be made over the entire sensing range, for example, to detect both [Cl − ] ions and biomolecules in portable diagnostics [9,10].…”

Section: Introductionmentioning

confidence: 99%

Unusual Operation of the Junction Transistor Based on Dynamical Behavior of Impurities

Baca-Arroyo

2018

Advances in Condensed Matter Physics

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The dynamical behavior of impurities into the silicon junction transistor has been studied using an empirical methodology to investigate its behavior knowing only the physical parameters of materials together with practical behavior of their passive components. The operating modes suggested with equations governing circuit performance are derived considering transient analysis. The relationship between material properties and equivalent circuit is discussed from a physical viewpoint. Theoretical solution of the equations yields a graphical response as approximation of the experimental results obtained from a proposed circuit built with an inductor and an NPN silicon MPSH10 transistor. Hence, the impurities-controlled electrical properties indicate that the observed unusual operation can be a good strategy to optimize signal processing in electronics.

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An Accurate BJT-Based CMOS Temperature Sensor With Duty-Cycle-Modulated Output

Cited by 48 publications

References 24 publications

A BJT-Based Temperature-to-Digital Converter With ±60 mK ( $3~\sigma$ ) Inaccuracy From −55 °C to +125 °C in 0.16-μm CMOS

A BJT-Based Temperature-to-Digital Converter With ±60 mK ( $3~\sigma$ ) Inaccuracy From −55 °C to +125 °C in 0.16-μm CMOS

CMOS based thermal detector for processor

Unusual Operation of the Junction Transistor Based on Dynamical Behavior of Impurities

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