Highly Linear Filtering TIA for 5G wireless standard and beyond

The demand for high data rates in emerging wireless standards is a result of the growing number of wireless device subscribers. This demand is met by increasing the channel bandwidth in accordance with historical trends. As MIMO technology advances, more bands and antennas are expected to be used. The most recent 5G standard makes use of mm-wave bands above 24GHz to expand the channel bandwidth. Channel bandwidth can exceed 2GHz when carrier aggregation is used. From the receiver’s point of view, this makes the baseband filter’s design, which is often a TIA, more difficult. This is due to the fact that as the bandwidth approaches the GHz range, the TIA’s UGBW should be more than 5GHz and it should have a high loop gain up to high frequencies. A closed-loop TIA with configurable bandwidth up to 1.5GHz is described in this scenario. Operational Transconductance Amplifier (OTA) closed in shunt-feedback is the foundation of the TIA. The proposed OTA is based on FeedForward topology (FF) together with inductive peaking technique to ensure stability rather than using the traditional Miller compensation technique. The TIA is able to produce GLoop unity gain bandwidth of 7.5GHz and high loop gain (i.e. 27dB @ 1GHz) using this method. The mixer and LNA’s linearity will benefit from this. Utilizing TSMC 28nm CMOS technology, a prototype has been created using this methodology. The output integrated noise from 20MHz to 1.5GHz is lower than 300μVrms with a power consumption of 17mW, and the TIA achieves In-band OIP3 of 33dBm. Additionally, a direct-conversion receiver for 5G applications is described. The 7GHz RF signal is down-converted to baseband by the receiver. Two cascaded LNTAs based on a common-gate transformer-based design make up the frontend. With an RF gain of 80mS and a gain variability of 31dB, it provides wideband matching from 6GHz to 8GHz. A double-balanced passive mixer is driven by the LNTA. The channel bandwidth from 50MHz to 2GHz is covered by two baseband paths. The first path, called as the low frequency path (LF), covers the channel bandwidth ranging from 50MHz to 400 MHz. In contrast, the second path, called as the high frequency path (HF), covers the channel bandwidth between 800MHz and 2GHz. Two baseband provide gain variability of 14dB, making the overall receiver able to have a gain configurability from 45dB to 0dB. Out-of-band (OOB) selectivity at 4 times the band-edge is greater than 33dB for each configurability. When the gain is at its maximum, the noise figure is less than 5.8dB, and the slope of the noise rise as the gain falls is less than 0.7dB/dB. The receiver guarantee an IB-OIP3 larger than 21dBm for any gain configuration. The receiver has been implemented in TSMC 28nm CMOS technology, consuming 51mW for LF path and 68mW for HF path. The measurement results are in perfect accordance with the requirements of the design

A 0.1–5.0 GHz flexible SDR receiver with digitally assisted calibration in 65 nm CMOS

© 2017 Elsevier Ltd. All rights reserved.A 0.1–5.0 GHz flexible software-defined radio (SDR) receiver with digitally assisted calibration is presented, employing a zero-IF/low-IF reconfigurable architecture for both wideband and narrowband applications. The receiver composes of a main-path based on a current-mode mixer for low noise, a high linearity sub-path based on a voltage-mode passive mixer for out-of-band rejection, and a harmonic rejection (HR) path with vector gain calibration. A dual feedback LNA with “8” shape nested inductor structure, a cascode inverter-based TCA with miller feedback compensation, and a class-AB full differential Op-Amp with Miller feed-forward compensation and QFG technique are proposed. Digitally assisted calibration methods for HR, IIP2 and image rejection (IR) are presented to maintain high performance over PVT variations. The presented receiver is implemented in 65 nm CMOS with 5.4 mm2 core area, consuming 9.6–47.4 mA current under 1.2 V supply. The receiver main path is measured with +5 dB m/+5dBm IB-IIP3/OB-IIP3 and +61dBm IIP2. The sub-path achieves +10 dB m/+18dBm IB-IIP3/OB-IIP3 and +62dBm IIP2, as well as 10 dB RF filtering rejection at 10 MHz offset. The HR-path reaches +13 dB m/+14dBm IB-IIP3/OB-IIP3 and 62/66 dB 3rd/5th-order harmonic rejection with 30–40 dB improvement by the calibration. The measured sensitivity satisfies the requirements of DVB-H, LTE, 802.11 g, and ZigBee.Peer reviewedFinal Accepted Versio

대역 외 방해신호에 내성을 가지는 광대역 수신기에 관한 연구

학위논문 (박사)-- 서울대학교 대학원 : 공과대학 전기·컴퓨터공학부, 2018. 2. 남상욱.In this thesis, a study of wideband receivers as one of the practical SDR receiver implementations is presented. The out-of-band interference signal (or blocker), which is the biggest problem of the wideband receiver is investigated, and have studied how to effectively remove it. As a result of reviewing previous studies, we have developed a wideband receiver based on the current-mode receiver structure and attempted to eliminate the blocker. The contents of the step-by-step research are as follows. First, attention was paid to the linearity of a low-noise transconductance amplifier (LNTA), which is the base block of current-mode receivers. In current-mode receivers, the LNTA should have a high transconductance (Gm) value to achieve a low noise figure, but a high Gm value results in low linearity. To solve this trade-off, we proposed a linearization method of transconductors. The proposed technique eliminates the third-order intermodulation distortion (IMD3) in a feed-forward manner using two paths. A transconductor having a transconductance of 2Gm is disposed in the main path, and an amplifier having a gain of ∛2 and a Gm-sized transconductor are located in the auxiliary path. This structure allows for some fundamental signal loss but cancel the IMD3 component at the output. As a result, the entire transconductor circuit can have high linearity due to the removed IMD3 component. We have designed a reconfigurable high-pass filter using a linearized transconductor and have demonstrated its performance. The fabricated circuit achieved a high input-referred third-order intercept point(IIP3) performance of 19.4 dBm. Then, a further improved linearized transconductor is designed. Since the linearized transconductors have a high noise figure due to the additional circuitry used for linearization, we have proposed a more suitable form for application to LNTA through noise figure analysis. The improved LNTA is designed to operate in low noise mode when there is no blocker, and can be switched to operate in high linearity mode when the blocker exists. We also applied noise cancelling techniques to the receiver to improve the noise figure performance of the wideband receiver circuit. A feedback path has been added to the current-mode receiver structure consisting of the LNTA, the mixer and the baseband transimpedance amplifier (TIA), and the noise signal can be detected using this path. This feedback path also maintains the input matching of the receiver to 50 Ω in a wide bandwidth. By adding an auxiliary path to the receiver, the in-band signal is amplified and the detected noise is removed from the baseband. The completed circuit exhibited wideband performance from 0.025 GHz to 2 GHz and IIP3 performance of -6.9 dBm in the high linearity mode. Finally, we designed a double noise-cancelling wideband receiver circuit by improving the performance of a wideband receiver with high immunity to blocker signals. In previous receivers, the LNTA was operated in two modes depending on the situation. In the improved receiver, the Gm ratio of the linearized LNTA was changed and the RF noise-cancelling technique was applied. The input matching and noise cancelling scheme introduced in the previous circuit was also applied and a wideband receiver circuit was designed to perform double noise-cancelling. As a result, the linearization and noise-cancellation of LNTA could be achieved at the same time, and the completed receiver circuit showed high IIP3 performance of 5 dBm with minimum noise figure of 1.4 dB. In conclusion, this thesis proposed a linearization technique for transconductor circuit and designed a wideband receiver based on current-mode receiver. The designed receiver circuit experimentally verified that it has low noise figure performance and high IIP3 performance and is tolerant to out-of-band blocker signals.Chapter 1. Introduction 1 1.1. Motivation of Wideband Receiver Architecture 2 1.2. Challenges in Designing Wideband Receiver 7 1.3. Prior Researches 13 1.3.1. N-Path Filter 14 1.3.2. Feed-Forward Blocker Filtering 16 1.3.3. Current-Mode Receiver 18 1.4. Research Objectives and Thesis Organization 22 Chapter 2. Transconductor Linearization Technique and Design of Tunable High-pass Filter 24 2.1. Transconductor Linearization Technique 27 2.2. Design of Tunable High-pass Filter 36 2.3. Measurement Results 41 2.4. Conclusions 46 Chapter 3. Wideband Noise-Cancelling Receiver Front-End Using Linearized Transconductor 47 3.1. Low-Noise Transconductance Amplifier Based on Linearized Transconductor 49 3.2. Wideband Noise-Cancelling Receiver Architecture 58 3.3. Measurement Results 64 3.4. Conclusions 70 Chapter 4. Blocker-Tolerant Wideband Double Noise-Cancelling Receiver Front-End 71 4.1. Linearized Noise-Cancelling Low-Noise Transconductance Amplifier 73 4.2. Wideband Double Noise-Cancelling Receiver Front-End 83 4.3. Measurement Results 90 4.4. Conclusions 97 Chapter 5. Conclusions 98 Bibliography 102 Abstract in Korean 112Docto

Inductorless LNA and Harmonic-rejection Mixer for Wideband Direct-conversion Receiver

In this master thesis, combinations of noise-canceling LNA and harmonic-rejection mixers are investigated and compared to find an optimal inductorless receiver front-end for low-band (600-960MHz) FDD LTE-A network. The work was carried out in a modem development project at Ericsson Modems, Lund. Three receiver versions with different harmonic rejection techniques are compared in terms of noise figure (NF) and power consumption and the receiver with 6 LO phases is selected for optimization. The LNA combines noise cancellation for matching stage and nonlinearity cancellation for output stages so both low noise figure and high linearity are achieved. The final circuit show great potential for FDD LTE-A system with support up to 3 aggregated carriers for higher bandwidth. Low NF at 1.62 dB after the LNA and 1.75 dB after the mixer are observed from 0.4-1GHz. The LNA IIP2 is above 12 dBm and robust with process and temperature. Gain switching with possible reduction of 6 and 12 dB is integrated and the LNA linearity is not significantly suffered by low gain. Input return loss (S11) is better than -12dB regardless of gain, number of carriers and temperature (-30 – 110°C). Inductorless operation saves a lot of chip area and avoid dead package area, which then save cost and make the solution competitive.This master’s thesis done at Ericsson Modem aimed to investigate an inductorless receiver front-end for low-band LTE-A user terminals. The circuit combined noise-canceling technique and push-pull stage for LNA and harmonic-rejection technique for mixer, so three main issues of inductorless operation are solved. The issues include LNA noise and linearity, and noise folding effect caused by 3rd harmonics of LO signals

Monolithic Transformers for RF Electronics

In this thesis transformers for RF integrated circuits are investigated. Monolithic transformers are widely used in various RF and high frequency circuits. For instance, transformers are used as power combiners in power amplifiers, in small signal amplifiers they are used for advanced feedback arrangements, they enable integrated filter implementation, they are used as baluns and impedance matching networks, and they can be used as resonators in oscillators. Unfortunately foundry supported models for on-chip transformers are rarely available and circuit designers need to design and characterize their own transformers using electro magnetic (EM) field simulator. This is a time consuming and laborious task, yet rigorous optimization of transformer characteristics results in significant improvements. Therefore one of the aims of this thesis was to develop an automated EM simulator environment. The thesis starts with representation of transformer basics and then different types of structures for such devices are introduced and discussed. One structure called "Interleaved Transformer" is chosen to be the basis of the design for its good magnetic coupling, symmetry, high frequency range and need of only two layers. More than 50 samples of these devices are designed and characterized. This is done with the help of an automated layout drawing program that was developed in this thesis. Afterwards, they are compared to illustrate how changing the dimensions can help us achieve desired properties. From these comparisons we have generated guidelines on how to for instance maximize quality factor, band width, or coupling coefficient. Based on these findings we can conclude what dimensional properties are needed for a specific circuit requirement and finally find out how to choose correct transformer dimensions for given applications

Advances in Integrated Circuit Design and Implementation for New Generation of Wireless Transceivers

User’s everyday outgrowing demand for high-data and high performance mobile devices pushes industry and researchers into more sophisticated systems to fulfill those expectations. Besides new modulation techniques and new system designs, significant improvement is required in the transceiver building blocks to handle higher data rates with reasonable power efficiency. In this research the challenges and solution to improve the performance of wireless communication transceivers is addressed. The building block that determines the efficiency and battery life of the entire mobile handset is the power amplifier. Modulations with large peak to average power ratio severely degrade efficiency in the conventional fixed-biased power amplifiers (PAs). To address this challenge, a novel PA is proposed with an adaptive load for the PA to improve efficiency. A nonlinearity cancellation technique is also proposed to improve linearity of the PA to satisfy the EVM and ACLR specifications. Ultra wide-band (UWB) systems are attractive due to their ability for high data rate, and low power consumption. In spite of the limitation assigned by the FCC, the coexistence of UWB and NB systems are still an unsolved challenge. One of the systems that is majorly affected by the UWB signal, is the 802.11a system (5 GHz Wi-Fi). A new analog solution is proposed to minimize the interference level caused by the impulse Radio UWB transmitter to nearby narrowband receivers. An efficient 400 Mpulse/s IR-UWB transmitter is implemented that generates an analog UWB pulse with in-band notch that covers the majority of the UWB spectrum. The challenge in receiver (RX) design is the over increasing out of blockers in applications such as cognitive and software defined radios, which are required to tolerate stronger out-of-band (OB) blockers. A novel RX is proposed with a shunt N-path high-Q filter at the LNA input to attenuate OB-blockers. To further improve the linearity, a novel baseband blocker filtering techniques is proposed. A new TIA has been designed to maintain the good linearity performance for blockers at large frequency offsets. As a result, a +22 dBm IIP3 with 3.5 dB NF is achieved. Another challenge in the RX design is the tough NF and linearity requirements for high performance systems such as carrier aggregation. To improve the NF, an extra gain stage is added after the LNA. An N-path high-Q band-pass filter is employed at the LNA output together with baseband blocker filtering technique to attenuate out-of-band blockers and improve the linearity. A noise-cancellation technique based on the frequency translation has been employed to improve the NF. As a result, a 1.8dB NF with +5 dBm IIP3 is achieved. In addition, a new approach has been proposed to reject out of band blockers in carrier aggregation scenarios. The proposed solution also provides carrier to carrier isolation compared to typical solution for carrier aggregation

CMOS ASIC Design of Multi-frequency Multi-constellation GNSS Front-ends

With the emergence of the new global navigation satellite systems (GNSSs) such as Galileo, COMPASS and GLONASS, the US Global Positioning System (GPS) has new competitors. This multiplicity of constellations will offer new services and a much better satellite coverage. Public regulated service (PRS) is one of these new services that Galileo, the first global positioning service under civilian control, will offers. The PRS is a proprietary encrypted navigation designed to be more reliable and robust against jamming and provides premium quality in terms of position and timing and continuity of service, but it requires the use of FEs with extended capabilities. The project that this thesis starts from, aims to develop a dual frequency (E1 and E6) PRS receiver with a focus on a solution for professional applications that combines affordability and robustness. To limit the production cost, the choice of a monolithic design in a multi-purpose 0.18 µm complementary metal-oxide-semiconductor (CMOS) technology have been selected, and to reduce the susceptibility to interference, the targeted receiver is composed of two independent FEs. The first ASIC described here is such FEs bundle. Each FE is composed of a radio frequency (RF) chain that includes a low-noise amplifier (LNA), a quadrature mixer, a frequency synthesizer (FS), two intermediate frequency (IF) filters, two variable-gain amplifiers (VGAs) and two 6-bit flash analog-to-digital converters (ADCs). Each have an IF bandwidth of 50 MHz to accommodate the wide-band PRS signals. The FE achieves a 30 dB of dynamic gain control at each channel. The complete receivers occupies a die area of 11.5 mm2 while consuming 115 mW from a supply of a 1.8 V. The second ASIC that targets civilian applications, is a reconfigurable single-channel FE that permits to exploit the interoperability among GNSSs. The FE can operate in two modes: a ¿narrow-band mode¿, dedicated to Beidou-B1 with an IF bandwidth of 8 MHz, and a ¿wide-band mode¿ with an IF bandwidth of 23 MHz, which can accommodate simultaneous reception of Beidou-B1/GPS-L1/Galileo-E1. These two modes consumes respectively 22.85 mA and 28.45 mA from a 1.8 V supply. Developed with the best linearity in mind, the FE shows very good linearity with an input-referred 1 dB compression point (IP1dB) of better than -27.6 dBm. The FE gain is stepwise flexible from 39 dB and to a maximum of 58 dB. The complete FE occupies a die area of only 2.6 mm2 in a 0.18 µm CMOS. To also accommodate the wide-band PRS signals in the IF section of the FE, a highly selective wide-tuning-range 4th-order Gm-C elliptic low-pass filter is used. It features an innovative continuous tuning circuit that adjusts the bias current of the Gm cell¿s input stage to control the cutoff frequency. With this circuit, the power consumption is proportional to the cutoff frequency thus the power efficiency is achieved while keeping the linearity near constant. Thanks to a Gm switching technique, which permit to keep the signal path switchless, the filter shows an extended tuning of the cutoff frequency that covers continuously a range from 7.4 MHz to 27.4 MHz. Moreover the abrupt roll-off of up to 66 dB/octave, can mitigate out-of-band interference. The filter consumes 2.1 mA and 7.5 mA at its lowest and highest cutoff frequencies respectively, and its active area occupies, 0.23 mm2. It achieves a high input-referred third-order intercept point (IIP3) of up to -1.3 dBVRMS