A CMOS LNA for 3.1-10.6GHz Ultra-Wideband

Lin, Shin-Yang

25 January 2011

The objective of this thesis is aimed at the design of low noise amplifier (LNA) for an ultra-wideband (UWB) receiver system using standard 0.18um CMOS process. A two amplified stage topology is proposed in the low noise amplifier. The first stage introduces inductively source degeneration, it can achieve wideband input impedance matching. The second stage introduces traditional CS configuration, it can improve the forward gain (S21). The second stage also used L-C section for output match. In order to improve the gain at high frequency, we introduces the series peaking between the first stage and second stage. We use the resistive-feedback between second stage and output, it can achieve wideband output impedance matching. The total power dissipation of the low noise amplifier is about 16.5mW at power supply 1.5 volt and the chip size is 920*940mm2. The simulated result shows that S11 is under -9dB, S22 is under -10dB, the forward gain S21 is 11.63dB~12.56dB at 3.1-10.6GHz, the reverse isolation S12 is under -32dB, and the noise figure is3.3dB~3.96dB.

low noise amplifier

input matching

Series-peaking

Resistive-feedback

Ultra-wideband

CMOS

Design of an UWB CMOS Low Noise Amplifier with Series-peaking

Miao, Jen-hao

25 January 2010

The objective of this thesis is aimed at the design of low noise amplifier (LNA) for an ultra-wideband (UWB) receiver system using standard 0.18um CMOS process. A two amplified stage topology is proposed in the low noise amplifier. The first stage introduces inductively source degeneration and resistive-feedback, it can achieve wideband input impedance matching. The second stage introduces traditional CS configuration, it can improve the forward gain (S21). The second stage also used L-C section for output match. In order to improve the gain at high frequency, we introduces the series peaking between the first stage and second stage. The total power dissipation of the low noise amplifier is about 24.3mW at power supply 1.5 volt and the chip size is 1.283*1.008mm2. The simulated result shows that S11 is under -8dB, S22 is under -10dB, the forward gain S21 is 12.6dB~15.3dB at 3.1-10.6GHz, the reverse isolation S12 is under -30dB, and the noise figure is 3.24dB~4.84dB.

Input Matching

Series-peaking

Low Noise Amplifier

Resistive-feedback

Ultra-wideband

CMOS

Picoampere Streaming Current Measuring Unit for a Microchip Biosensor

Kamalmaz, Mohammed Nour

January 2024

Measuring low electrical currents with high precision is critical across various fields, particularly in applications like microfluidic biosensing. Traditional digital multimeters (DMMs) are inadequate for low current measurements due to their high input burden and limited resolution. Therefore, more sensitive instruments like electrometers and picoammeters are often required but are typically expensive. This thesis explores the design and construction of a cost-effective, portable, and user-friendly picoammeter based on a transimpedance amplifier (TIA), capable of measuring currents in the picoampere (pA) range with a resolution of 1-5 pA and minimal noise. The constructed picoammeter has a maximum input current range of ±1.5 nA.  A prototype was built on a soldering board to validate the design, which was then translated into a practical printed circuit board (PCB) layout. The device is powered by batteries to ensure low noise levels and enable isolated operation. An Arduino microcontroller was used to interface with the circuit, manage data acquisition, and enable real-time visualisation of the measured current data on a computer.  Simulation results confirmed the theoretical performance of the circuit, and experimental validation showed RMS noise levels of less than 0.3 pA under controlled conditions and up to 3 pA when measuring streaming currents from a microchip. Despite a slight underestimation of input currents due to resistor tolerances, calibration adjustments successfully corrected these discrepancies.  The total cost of the materials used in constructing the picoammeter was significantly less than the cost of commercially available devices. While commercial devices offer higher precision and additional functionalities, the developed picoammeter demonstrates how application-focused solutions can provide comparable accuracy and noise characteristics to commercial devices for a fraction of the price.

Picoammeter

Transimpedance amplifier

TIA

Resistive feedback picoammeter

Streaming current

Annan elektroteknik och elektronik

Low-power CMOS front-ends for wireless personal area networks

Perumana, Bevin George

30 October 2007

The potential of implementing subthreshold radio frequency circuits in deep sub-micron CMOS technology was investigated for developing low-power front-ends for wireless personal area network (WPAN) applications. It was found that the higher transconductance to bias current ratio in weak inversion could be exploited in developing low-power wireless front-ends, if circuit techniques are employed to mitigate the higher device noise in subthreshold region. The first fully integrated subthreshold low noise amplifier was demonstrated in the GHz frequency range requiring only 260 μW of power consumption. Novel subthreshold variable gain stages and down-conversion mixers were developed. A 2.4 GHz receiver, consuming 540 μW of power, was implemented using a new subthreshold mixer by replacing the conventional active low noise amplifier by a series-resonant passive network that provides both input matching and voltage amplification. The first fully monolithic subthreshold CMOS receiver was also implemented with integrated subthreshold quadrature LO (Local Oscillator) chain for 2.4 GHz WPAN applications. Subthreshold operation, passive voltage amplification, and various low-power circuit techniques such as current reuse, stacking, and differential cross coupling were combined to lower the total power consumption to 2.6 mW. Extremely compact resistive feedback CMOS low noise amplifiers were presented as a cost-effective alternative to narrow band LNAs using high-Q inductors. Techniques to improve linearity and reduce power consumption were presented. The combination of high linearity, low noise figure, high broadband gain, extremely small die area and low power consumption made the proposed LNA architecture a compelling choice for many wireless applications.

Low-power circuits

Wireless front-end circuits

Subthreshold wireless receiver

Subthrehsold CMOS

Wireless personal area networks

Resistive feedback LNA

Wireless communication systems

Radio frequency integrated circuits