A 300-800MHz Tunable Filter and Linearized LNA applied in a Low-Noise Harmonic-Rejection RF-Sampling Receiver

A multiband flexible RF-sampling receiver aimed at software-defined radio is presented. The wideband RF sampling function is enabled by a recently proposed discrete-time mixing downconverter. This work exploits a voltage-sensing LNA preceded by a tunable LC pre-filter with one external coil to demonstrate an RF-sampling receiver with low noise figure (NF) and high harmonic rejection (HR). The second-order LC filter provides voltage pre-gain and attenuates the source noise aliasing, and it also improves the HR ratio of the sampling downconverter. The LNA consists of a simple amplifier topology built from inverters and resistors to improve the third-order nonlinearity via an enhanced voltage mirror technique. The RF-sampling receiver employs 8 times oversampling covering 300 to 800 MHz in two RF sub-bands. The chip is realized in 65 nm CMOS and the measured gain across the band is between 22 and 28 dB, while achieving a NF between 0.8 to 4.3 dB. The IIP2 varies between +38 and +49 dBm and the IIP3 between -14 dBm and -9 dBm, and the third and fifth order HR ratios are more than 60 dB. The LNA and downconverter consumes 6 mW, and the clock generator takes 12 mW at 800 MHz RF.\ud \u

Digitally-Enhanced Software-Defined Radio Receiver Robust to Out-of-Band Interference

A software-defined radio (SDR) receiver with improved robustness to out-of-band interference (OBI) is presented. Two main challenges are identified for an OBI-robust SDR receiver: out-of-band nonlinearity and harmonic mixing. Voltage gain at RF is avoided, and instead realized at baseband in combination with low-pass filtering to mitigate blockers and improve out-of-band IIP3. Two alternative “iterative” harmonic-rejection (HR) techniques are presented to achieve high HR robust to mismatch: a) an analog two-stage polyphase HR concept, which enhances the HR to more than 60 dB; b) a digital adaptive interference cancelling (AIC) technique, which can suppress one dominating harmonic by at least 80 dB. An accurate multiphase clock generator is presented for a mismatch-robust HR. A proof-of-concept receiver is implemented in 65 nm CMOS. Measurements show 34 dB gain, 4 dB NF, and 3.5 dBm in-band IIP3 while the out-of-band IIP3 is + 16 dBm without fine tuning. The measured RF bandwidth is up to 6 GHz and the 8-phase LO works up to 0.9 GHz (master clock up to 7.2 GHz). At 0.8 GHz LO, the analog two-stage polyphase HR achieves a second to sixth order HR > dB over 40 chips, while the digital AIC technique achieves HR > 80 dB for the dominating harmonic. The total power consumption is 50 mA from a 1.2 V supply

Auxiliary-Path-Assisted Digital Linearization of Wideband Wireless Receivers

Wireless communication systems in recent years have aimed at increasing data rates by ensuring flexible and efficient use of the radio spectrum. The dernier cri in this field has been in the area of carrier aggregation and cognitive radio. Carrier aggregation is a major component of LTE-Advanced. With carrier aggregation, a number of separate LTE carriers can be combined, by mobile network operators, to increase peak data rates and overall network capacity. Cognitive radios, on the other hand, allow efficient spectrum usage by locating and using spatially vacant spectral bands. High monolithic integration in these application fields can be achieved by employing receiver architectures such as the wideband direct conversion receiver topology. This is advantageous from the view point of cost, power consumption and size. However, many challenges exist, of particular importance is nonlinear distortion arising from analog front-end components such as low noise amplifiers (LNA). Nonlinear distortions especially become severe when several signals of varying amplitudes are received simultaneously. In such cases, nonlinear distortions stemming from strong signals may deteriorate the reception of the weaker signals, and also impair the receiver’s spectrum sensing capabilities. Nonlinearity, usually a consequence of dynamic range limitation, degrades performance in wideband multi-operator communications systems, and it will have a notable role in future wireless communication system design. This thesis presents a digital domain linearization technique that employs a very nonlinear auxiliary receiver path for nonlinear distortion cancellation. The proposed linearization technique relies on one-time adaptively-determined linearization coefficients for cancelling nonlinear distortions. Specifically, we take a look at canceling the troublesome in-band third order intermodulation products using the proposed technique. The proposed technique can be extended to cancel out both even and higher order odd intermodulation products. Dynamic behavioral models are used to account for RF nonlinearities, including memory effects which cannot be ignored in the wideband scenario. Since the proposed linearization technique involves the use of two receiver paths, techniques for correcting phase delays between the two paths are also introduced. Simplicity is the hallmark of the proposed linearization technique. It can achieve up to +30 dBm in IIP3 performance with ADC resolution being a major performance bottleneck. It also shows strong tolerance to strong blocker nonlinearities

Amplifier Architectures for Wireless Communication Systems

Ever-increasing demand in modern wireless communication systems leads researchers to focus on design challenges on one of the main components of RF transmitters and receivers, namely amplifiers. On the transmitter side, enhanced efficiency and broader bandwidth over single and multiple bands on power amplifiers will help to have superior performance in communication systems. On the other hand, for the receiver side, having low noise and high gain will be necessary to ensure good quality transmission over such systems. In light of these considerations, a unique approach in design methodologies are studied with low noise amplifiers (LNAs) for RF receivers and the Doherty technique is analyzed for efficiency enhancement for power amplifiers (PA) on the transmitters. This work can be outlined in two parts. In the first part, Low Noise RF amplifier designs with Bipolar Junction Transistor (BJT) are studied to achieve better performing LNAs for receivers. The aim is to obtain a low noise figure while optimizing the bandwidth and achieving a maximum available gain. There are two designs that are operating at different center frequencies and utilizing different transistors. The first design is a wideband low-noise amplifier operating at 2 GHz with a high power BJT. The proposed design uses only distributed elements to realize the input and output matching networks. Additionally, a passive DC bias network is used instead of an active DC bias network to avoid possible complications due to the lumped elements parasitic effects. The matching networks are designed based on the reflection coefficients that are derived based on the transistor’s available regions. The second design is a low voltage standing wave ratio (VSWR) amplifier with a low noise figure operating at 3 GHz. This design is following the same method as in the first design. Both these amplifiers are designed to operate in broadband applications and can be good candidates for base stations. The second part of this work focuses on the transmitter side of communication systems. For this part, Doherty Power Amplifier (DPA) is analyzed as an efficiency enhancement technique for PAs. A modified architecture is proposed to have wider bandwidth and higher efficiency. In the proposed design, the quarter-wave impedance inverter was eliminated. The input and the output of the main and peak amplifiers are matched to the load directly. Additionally, the input and output matching networks are realized only using distributed elements. The selected transistor for this design is a 10 W Gallium Nitride (GaN). The fabricated amplifier operates at the center frequency of 2 GHz and provides 40% fractional bandwidth, 54% of maximum power-added efficiency, and 12.5 dB or better small-signal gain. The design is showing promising results to be a good candidate for better-performing transmitters over the L- and S- band

Digitally-Assisted RF IC Design Techniques for Reliable Performance

Semiconductor industries have competitively scaled down CMOS devices to attain benefits of low cost, high performance, and high integration density in digital integrated circuits. On the other hand, deep scaled technologies inextricably accompany a large process variation, supply voltage scaling, and reduction in breakdown voltages of transistors. When it comes to RF/analog IC design, CMOS scaling adversely affects its reliability due to large performance variation and limited linearity. For addressing the issues related to variations and linearity, this research proposes the following digitally-assisted RF circuit design techniques: self-calibration system for RF phase shifters and wide dynamic range LNAs. Due to PVT variations in scaled technologies, RF phase shifter design becomes more challenging with device scaling. In the proposed self-calibration topology, we devised a novel phase sensing method and a pulsewidth-to-digital converter. The feedback controller is also designed in digital domain, which is robust to PVT variations. These unique techniques enable a sensing/control loop tolerant to PVT variations. The self-calibration loop was applied to a 7 to 13GHz phase shifter. With the calibration, the estimated phase error is less than 2 degrees. To overcome the linearity issue in scaled technologies, a digitally-controlled dual-mode LNA design is presented. A narrowband (5.1GHz) and a wideband (0.8 to 6GHz) LNA can be toggled between high-gain and high-linearity modes by digital control bits according to the input signal power. A compact design, which provides negligible performance degradation by additional circuitry, is achieved by sharing most of the components between the two operation modes. The narrowband and the wideband LNA achieves an input-referred P1dB of -1.8dBm and +4.2dBm, respectively