Your search keyword '"Vasani, Anand"' showing total 4 results

1. A 3.8 mW/Gbps Quad-Channel 8.5–13 Gbps Serial Link With a 5 Tap DFE and a 4 Tap Transmit FFE in 28 nm CMOS.

Author

Kocaman, Namik, Ali, Tamer, Rao, Lakshmi P., Singh, Ullas, Abdul-Latif, Mohammed, Liu, Yang, Hafez, Amr Amin, Park, Henry, Vasani, Anand, Huang, Zhi, Iyer, Arvindh, Zhang, Bo, and Momtaz, Afshin

Subjects

CMOS integrated circuits, INTEGRATED circuit design, DATA transmission systems, DECISION feedback equalizers, EQUALIZERS (Electronics)

Abstract

This paper presents a quad-lane serial transceiver that supports virtually all data center communication standards around 8.5–13 Gbps, implemented in 28 nm CMOS technology. The transmitter consists of 20:2 mux followed by a half-rate source-series terminated (SST) driver embedded with a 4 tap FFE and an analog equalizer. The receiver has an adaptive CTLE, 5 tap DFE, and fully digital CDR followed by 2:20 demux. At 13 Gbps, the transceiver can equalize 35 dB Nyquist loss at BER of 10-12. At 1.0 V supply, the transceiver consumes 49 mW/lane at 13 Gbps rate with full equalization capability. An LC VCO-based fractional PLL provides the clocking to quad TX/RX lanes using a low-power inductively tuned clock routing channel. The transceiver architecture not only enables the baud rate operation from 8.5 to 13 Gbps but also supports a wide range of oversampled subrates. This work represents the lowest reported power in its class to date, and the transceiver is suitable for many applications due to its comprehensive flexibility and power efficiency. [ABSTRACT FROM PUBLISHER]

Published

2016

2. A Dual-Channel 23-Gbps CMOS Transmitter/Receiver Chipset for 40-Gbps RZ-DQPSK and CS-RZ-DQPSK Optical Transmission.

Author

Cui, Delong, Raghavan, Bharath, Singh, Ullas, Vasani, Anand, Huang, Zhi, Pi, Deyi, Khanpour, Mehdi, Nazemi, Ali, Maarefi, Hassan, Zhang, Wei, Ali, Tamer, Huang, Nick, Zhang, Bo, Momtaz, Afshin, and Cao, Jun

Subjects

COMPLEMENTARY metal oxide semiconductors, RADIO transmitter-receivers, DIFFERENTIAL quadrature method, SIGNAL processing, PHASE-shifting interferometry, THRESHOLD logic

Abstract

This paper describes a dual-channel 23 (20 to 27) Gbps chipset designed in a 40-nm CMOS process for 40 Gbps differential quadrature phase-shift keying (DQPSK) optical transmission. The transmitter has a 2-tap FIR filter and generates two channels of full-rate data. Data outputs exhibit 10 ps rise/fall times, 0.2 psrms RJ, 0.8 pspp DJ, and a \pm \0.5 UI skew adjustment relative to the full-rate and half-rate clock outputs. The receiver has two 20–27-Gbps input channels, with each channel including a peaking filter, decision threshold adjustment, and 1-tap loop-unrolled DFE. It achieves a 7-mV ppd input sensitivity and a 0.7-UIpp high-frequency jitter tolerance. The transmitter and receiver dissipate 0.63 and 1.2 W, respectively. [ABSTRACT FROM AUTHOR]

Published

2012

3. 11.3 Gbps CMOS SONET Compliant Transceiver for Both RZ and NRZ Applications.

Author

Kocaman, Namik, Garg, Adesh, Raghavan, Bharath, Cui, Delong, Vasani, Anand, Tang, Keith, Pi, Deyi, Tong, Haitao, Fallahi, Siavash, Zhang, Wei, Singh, Ullas, Cao, Jun, Zhang, Bo, and Momtaz, Afshin

Subjects

COMPLEMENTARY metal oxide semiconductors, SONET (Data transmission), OPTICAL communications, SIGNAL processing, ELECTRIC resistors, INTEGRATED circuits, RADIO transmitter-receivers

Abstract

In this paper, an 11.3 Gbps CMOS SONET compliant transceiver designed to work in both RZ and NRZ data formats is presented. Using a configurable high-speed transmit path utilizing an AND gate and a duty cycle adjustment circuit, the transmitter can switch output format between RZ and NRZ. The TX driver exhibits 17 ps rise/fall times, 0.25 psrms RJ, and 2 pspp DJ. In RZ mode, TX output duty cycle can be adjusted within 40–60% range. To improve input sensitivity in both RZ and NRZ reception, the receiver incorporates a limiting amplifier with a distributed threshold adjustment circuit. It achieves 5 mVpp-diff RX input sensitivity with 0.54 UI high-frequency jitter tolerance. An adaptation scheme based on nested linear search is implemented to control the distributed threshold adjustment circuit. While demonstrating the integration of RZ/NRZ functionality into a single-chip solution using 65 nm CMOS technology, the transceiver core occupies 1.36 mm^2 and consumes 214 mW. [ABSTRACT FROM AUTHOR]

Published

2011

4. A dual 23Gb/s CMOS transmitter/receiver chipset for 40Gb/s RZ-DQPSK and CS-RZ-DQPSK optical transmission.

Author

Cui, Delong, Raghavan, Bharath, Singh, Ullas, Vasani, Anand, Huang, Zhi, Pi, Deyi, Khanpour, Mehdi, Nazemi, Ali, Maarefi, Hassan, Ali, Tamer, Huang, Nick, Zhang, Wei, Zhang, Bo, Momtaz, Afshin, and Cao, Jun

Abstract

Recently developed 40Gb/s optical modulation formats such as return-to-zero differential quadrature phase-shift keying (RZ-DQPSK) and carrier-suppressed return-to-zero differential quadrature phase-shift keying (CS-RZ-DQPSK) are promising, since they offer high optical signal-to-noise ratio, high transmission efficiency and can tolerate large chromatic dispersion [1, 2]. The recent advances in processing technology have opened the possibility of implementing these circuits in CMOS [3, 4]. This paper presents the first CMOS dual 20–27Gb/s chipset with equalization in transmitter and receiver as well as a clock to data skew adjustment. Both the transmitter and the receiver consume less power than those in previously published results [1–4]. [ABSTRACT FROM PUBLISHER]

Published

2012