Single-chip multiband WCDMA/HSDPA/HSUPA/EGPRS transceiver with diversity receiver and 3G DigRF interface without SAW filters in transmitter / 3G receiver paths

Sowlati, T.; Agarwal, B.; Cho, Joshua; Obkircher, Thomas; Said, Mohamed El; Vasa, J.; Ramachandran, Bala; Kahrizi, Masoud; Dagher, Elias H.; Chen, Weihong; Vadkerti, Martin; Taskov, Georgi; Seckin, Utku; Firouzkouhi, H.; Saeidi, Behzad; Akyol, Hasan; Choi, Yunyoung; Mahjoob, Amir; D'Souza, Sandeep; Hsieh, Chieh-Yu; David, Guss; Shum, D.K.; Badillo, D.A.; Imtiyaz, Ron; Ching, Doris; Shi, Feng; He, Yong; Komaili, Jaleh; Loke, A.; Pullela, R.; Pehlivanoglu, Engin; Zarei, Hamid Reza; Tadjpour, S.; Agahi, Darioush; Rozenblit, Dmitriy; Domino, William; Williams, Gregory; Damavandi, Nader; Wloczysiak, Stephane; Suhanthan, Rajendra; Paff, Aaron; Valencia, Tom

doi:10.1109/isscc.2009.4977335

Cited by 62 publications

(26 citation statements)

References 3 publications

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“…The proposed I-Q phase modulator adopts a double-balanced quadrature passive mixer topology to minimize LO leakage and so as to have low distortion. However, due to no reverse isolation in the passive mixer, an I-Q crosstalk problem occurs since one mixer switch from the I channel and the other mixer switch from the Q channel are simultaneously operating at any given moment [6]- [7]. To mitigate the I-Q crosstalk problem, instead of an LO-2LO mixer [6] or a 25% duty-cycle passive mixer [7], a passive mixer topology (described in [8]) has been modified and then used in this work.…”

Section: Circuit Designmentioning

confidence: 99%

“…However, due to no reverse isolation in the passive mixer, an I-Q crosstalk problem occurs since one mixer switch from the I channel and the other mixer switch from the Q channel are simultaneously operating at any given moment [6]- [7]. To mitigate the I-Q crosstalk problem, instead of an LO-2LO mixer [6] or a 25% duty-cycle passive mixer [7], a passive mixer topology (described in [8]) has been modified and then used in this work. The LO-2LO mixer and 25% duty-cycle mixer need additional circuits, such as LO buffers and LO clock generators.…”

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confidence: 99%

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3-Level Envelope Delta-Sigma Modulation RF Signal Generator for High-Efficiency Transmitters

Seo¹,

Cho

Choi

et al. 2014

ETRI J

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This paper presents a 0.13 μm CMOS 3-level envelope delta-sigma modulation (EDSM) RF signal generator, which synthesizes a 2.6 GHz-centered fully symmetrical 3-level EDSM signal for high-efficiency power amplifier architectures. It consists of an I-Q phase modulator, a Class B wideband buffer, an up-conversion mixer, a D2S, and a Class AB wideband drive amplifier. To preserve fast phase transition in the 3-state envelope level, the wideband buffer has an RLC load and the driver amplifier uses a second-order BPF as its load to provide enough bandwidth. To achieve an accurate 3-state envelope level in the up-mixer output, the LO bias level is optimized. The I-Q phase modulator adopts a modified quadrature passive mixer topology and mitigates the I-Q crosstalk problem using a 50% duty cycle in LO clocks. The fabricated chip provides an average output power of 1.5 dBm and an error vector magnitude (EVM) of 3.89% for 3GPP LTE 64 QAM input signals with a channel bandwidth of 10/20 MHz, as well as consuming 60 mW for both channels from a 1.2 V/2.5 V supply voltage.Keywords: CMOS, envelope delta-sigma modulation, EDSM, power amplifier, polar modulator, RF transmitter, 3GPP LTE. Manuscript received Feb. 18, 2014; revised July 3, 2014; accepted Aug. 5, 2014. This work was supported by National Research Foundation of Korea Grant funded by the Korean Government and also supported by the ICT R&D Program of MSIP/IITP (14-000-04-001, Development of 5G Mobile Communication Technologies for Hyper-connected Smart Services).Yongho Seo (syh3039@hanmail.net) I. IntroductionIn high-data-rate wireless systems, such as 3GPP Long-Term Evolution (LTE) and Worldwide Interoperability for Microwave Access (WiMAX), tremendous efforts to enhance power amplifier (PA) efficiency have led to new transmitter architectures employing a particular 1-bit encoder, such as delta-sigma modulation (DSM) or pulse-width modulation (PWM) [1]- [4]. However, due to such encoders having low coding efficiency, excessive power loss and efficiency degradation cannot be avoided. To enhance the cording efficiency of an encoder, we previously proposed the new transmitter architecture [5] shown in Fig. 1. In Fig. 1, a multilevel envelope delta-sigma modulation (ML-EDSM) scheme is used to enhance the coding efficiency using a 3-level (zero, A(t) max /2, and A(t) max ) envelope signal instead of a conventional 2-level signal. However, 3-level envelope modulation can degrade the PA efficiency, as the PA cannot operate in a saturated region under a single supply voltage for a middle-level envelope signal A(t) max /2. To overcome this problem, a dual-supply injection method is applied in the PA, as shown in Fig. 1. For the maximum-level envelope signal, A(t) max , the PA operates in the saturated region under a high supply voltage of V DD1 . However, when A(t) max becomes A(t) max /2, the dual-supply network switches V DD1 (V DD1 > V DD2 ) to the low supply voltage of V DD2 concurrently. Accordingly, the PA can always operate in the saturated region for the 3-level ...

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Section: Circuit Designmentioning

confidence: 99%

mentioning

confidence: 99%

3-Level Envelope Delta-Sigma Modulation RF Signal Generator for High-Efficiency Transmitters

Seo¹,

Cho

Choi

et al. 2014

ETRI J

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“…Even so called multimode/multiband and wide band transceivers have limitations and generally operate by switching front ends as required [19].…”

Section: Rf Front-ends Transceiver Challengesmentioning

confidence: 99%

Cognitive Radio RF: Overview and Challenges

Nguyen

Villain²,

Guillou³

2012

VLSI Design

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Cognitive radio system (CRS) is a radio system which is aware of its operational and geographical environment, established policies, and its internal state. It is able to dynamically and autonomously adapt its operational parameters and protocols and to learn from its previous experience. Based on software-defined radio (SDR), CRS provides additional flexibility and offers improved efficiency to overall spectrum use. CRS is a disruptive technology targeting very high spectral efficiency. This paper presents an overview and challenges of CRS with focus on radio frequency (RF) section. We summarize the status of the related regulation and standardization activities which are very important for the success of any emerging technology. We point out some key research challenges, especially implementation challenges of cognitive radio (CR). A particular focus is on RF front-end, transceiver, and analog-to-digital and digital-to-analog interfaces which are still a key bottleneck in CRS development.

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“…In the transmitter of [17], a feedback cancellation method is employed to suppress the noise of the on-chip diver. The transmitter presented in [18] uses Fig. 9: Multi-band low-noise upconverter that eliminates the need for a SAW filter between the PA driver and the power amplifier [19].…”

Section: Transmitter Designmentioning

confidence: 99%