Wide-Supply-Voltage-Range CMOS Bandgap Reference for In Vivo Wireless Power Telemetry

Zawawi, Ruhaifi Bin Abdullah; Abbasi, Wajahat H.; Kim, Seunghwan; Choi, Hojong; Kim, Jungsuk

doi:10.3390/en13112986

Cited by 13 publications

(12 citation statements)

References 21 publications

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“…The amplified signal can cause damage to the oscilloscope from a high voltage of 5 V P-P or greater. Therefore, the output signals were attenuated by a 40 dB attenuator, and the performances were measured using an oscilloscope [ 41 , 42 , 43 ]. To measure the performance of the amplifiers, the frequency and input signal amplitudes were adjusted using a function generator.…”

Section: Methodsmentioning

confidence: 99%

Novel Bandwidth Expander Supported Power Amplifier for Wideband Ultrasound Transducer Devices

Kim

Choi

2021

Sensors

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Ultrasound transducer devices have their own frequency ranges, depending on the applications and specifications, due to penetration depth, sensitivity, and image resolution. For imaging applications, in particular, the transducer devices are preferable to have a wide bandwidth due to the specific information generated by the tissue or blood vessel structures. To support these ultrasound transducer devices, ultrasound power amplifier hardware with a wide bandwidth can improve the transducer performance. Therefore, we developed a new bandwidth expander circuit using specially designed switching architectures to increase the power amplifier bandwidth. The measured bandwidth of the power amplifier with the help of the bandwidth expander circuit increased by 56.9%. In addition, the measured echo bandwidths of the 15-, 20-, and 25-MHz transducer devices were increased by 8.1%, 6.0%, and 9.8%, respectively, with the help of the designed bandwidth expander circuit. Therefore, the designed architecture could help an ultrasound system hardware with a wider bandwidth, thus supporting the use of different frequency ultrasound transducer devices with a single developed ultrasound system.

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Section: Methodsmentioning

confidence: 99%

Novel Bandwidth Expander Supported Power Amplifier for Wideband Ultrasound Transducer Devices

Kim

Choi

2021

Sensors

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“…The inductors at the gate and drain sides are choke inductors (L C = 1 µH), which could minimize the voltage drop when DC bias voltages were used [48][49][50]. In addition, the electrolytic capacitors (C G1 , C D3 , C G6 , and C D8 = 220 µF) and ceramic capacitors (C G2 , C D2 , C G7 , and C D7 = 1000 pF, C G3 , C D1 , C G8 , and C D6 = 47 pF) were used to minimize the noise signals from the DC power supply [51,52]. The input inductors, capacitors, and resistors (L G1 and L G3 = 22 nH, C G4 and C G9 = 560 pF, C G5 and C G10 = 330 pF, L G2 and L G4 = 1000 nH, and R G3 and R G6 = 200 Ω), and output inductors, capacitors, and resistors (L D1 and L D3 = 120 nH, C D4 and C D9 = 330 pF, C D5 and C D10 = 820 pF, L D2 and L D4 = 500 nH, and R D1 and R D2 = 200 Ω) in the firstand second-stage class-B amplifiers were configured for 50 Ω impedance matching conditions at a center frequency of 15 MHz.…”

Section: Schematic Of Class-b Amplifier and Post-voltage-boost Circuitmentioning

confidence: 99%

Post-Voltage-Boost Circuit-Supported Single-Ended Class-B Amplifier for Piezoelectric Transducer Applications

Kim

You

Choi

2020

Sensors

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Piezoelectric transducers are important devices that are triggered by amplifier circuits in mobile ultrasound systems. Therefore, amplifier performance is vital because it determines the acoustic piezoelectric transducer performances. Particularly, mobile ultrasound applications have strict battery performance and current consumption requirements; hence, amplifier devices should exhibit good efficiency because the direct current (DC) voltage in the battery are provided to the supply voltages of the amplifier, thus limiting the maximum DC drain voltages of the main transistors in the amplifier. The maximum DC drain voltages are related with maximum output power if the choke inductor in the amplifier is used. Therefore, a need to improve the amplifier performance of piezoelectric transducers exists for mobile ultrasound applications. In this study, a post-voltage-boost circuit-supported class-B amplifier used for mobile ultrasound applications was developed to increase the acoustic performance of piezoelectric transducers. The measured voltage of the post-voltage-boost circuit-supported class-B amplifier (62 VP-P) is higher than that of only a class-B amplifier (50 VP-P) at 15 MHz and 100 mVP-P input. By performing the pulse-echo measurement test, the echo signal with the post-voltage-boost circuit-supported class-B amplifier (10.39 mVP-P) was also noted to be higher than that with only a class-B amplifier (6.15 mVP-P). Therefore, this designed post-voltage-boost circuit can help improve the acoustic amplitude of piezoelectric transducers used for mobile ultrasound applications.

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“…The current paper is an extension of our previous work in [12]. Our last work utilizes the temperature compensation technique, which had been proven to reduce the variation of the reference voltage at higher temperatures.…”

Section: Introductionmentioning

confidence: 98%

“…The proposed circuit was also evaluated in the full-path retinal prosthetic system shown in Section 3. This system includes on-chip digital controller and stimulator, which is not implemented in [12].…”

Section: Introductionmentioning

confidence: 99%

High-PSRR Wide-Range Supply-Independent CMOS Voltage Reference for Retinal Prosthetic Systems

2020

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This paper presents a fully integrated voltage-reference circuit for implantable devices such as retinal implants. The recently developed retinal prostheses require a stable supply voltage to drive a high-density stimulator array. Accordingly, a voltage-reference circuit plays a critical role in generating a constant reference voltage, which is provided to a low-voltage-drop regulator (LDO), and filtering out the AC ripples in a power-supply rail after rectification. For this purpose, we use a beta-multiplier voltage-reference architecture to which a nonlinear current sink circuit is added, to improve the supply-independent performance drastically. The proposed reference circuit is fabricated using the standard 0.35 µm technology, along with an LDO that adopts an output ringing compensation circuit. The novel reference circuit generates a reference voltage of 1.37 V with a line regulation of 3.45 mV/V and maximum power-supply rejection ratio (PSRR) of −93 dB.

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Wide-Supply-Voltage-Range CMOS Bandgap Reference for In Vivo Wireless Power Telemetry

Cited by 13 publications

References 21 publications

Novel Bandwidth Expander Supported Power Amplifier for Wideband Ultrasound Transducer Devices

Novel Bandwidth Expander Supported Power Amplifier for Wideband Ultrasound Transducer Devices

Post-Voltage-Boost Circuit-Supported Single-Ended Class-B Amplifier for Piezoelectric Transducer Applications

High-PSRR Wide-Range Supply-Independent CMOS Voltage Reference for Retinal Prosthetic Systems

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