Dongsoo Koh

An Embedded 65 nm CMOS Baseband IQ 48 MHz–1 GHz Dual Tuner for DOCSIS 3.0

An embedded CMOS digital dual tuner for DOCSIS 3.0 and set-top box applications is presented. The dual tuner down-converts a total of ten 6 MHz Annex B channels or eight 8 MHz Annex A channels, for a maximum data rate of 320 Mb/s in Annex B and 400 Mb/s in Annex A mode. The dual tuner exceeds all the stringent SCTE 40 specifications over the 48-1004 MHz bandwidth, without using any external components or SAW filters. Enabling technologies are a harmonic rejection front-end, a low-noise high-frequency resolution PLL, and digital image rejection. To our knowledge this is the first reported multichannel broadband tuner embedded in a DOCSIS 3.0 System on a chip implemented in 65 nm pure digital CMOS technology.

An embedded 65 nm CMOS baseband IQ 48 MHz-1 GHz dual tuner for DOCSIS 3.0

An embedded CMOS digital dual tuner for DOCSIS 3.0 and set-top box applications is presented. The dual tuner down-converts a total of ten 6 MHz Annex B channels or eight 8 MHz Annex A channels, for a maximum data rate of 320 Mb/s in Annex B and 400 Mb/s in Annex A mode. The dual tuner exceeds all the stringent SCTE 40 specifications over the 48-1004 MHz bandwidth, without using any external components or SAW filters. Enabling technologies are a harmonic rejection front-end, a low-noise high-frequency resolution phase-locked loop (PLL) and digital image rejection. To our knowledge this is the first reported multi-channel Broadband Tuner embedded in a DOCSIS 3.0 System on a Chip implemented in a 65 nm pure digital CMOS technology.

27.6 A 4GS/s 13b pipelined ADC with capacitor and amplifier sharing in 16nm CMOS

In recent years, we have seen the emergence of multi-GS/s medium-to-high-resolution ADCs. Presently, SAR ADCs dominate low-speed applications and time-interleaved SARs are becoming increasingly popular for high-speed ADCs [1,2]. However the SAR architecture faces two key problems in simultaneously achieving multi-GS/s sample rates and high resolution: (1) the fundamental trade-off of comparator noise and speed is limiting the speed of single-channel SARs, and (2) highly time-interleaved ADCs introduce complex lane-to-lane mismatches that are difficult to calibrate with high accuracy. Therefore, pipelined [3] and pipelined-SAR [4] remain the most common architectural choices for high-speed high-resolution ADCs. In this work, a pipelined ADC achieves 4GS/s sample rate, using a 4-step capacitor and amplifier-sharing front-end MDAC architecture with 4-way sampling to reduce noise, distortion and power, while overcoming common issues for SHA-less ADCs.

An embedded 65nm CMOS low-IF 48MHz-to-1GHz dual tuner for DOCSIS 3.0

The increased competition to deliver broadband data to the home (including GPON and VDSL) is motivating cable providers to deliver data rates which far exceed what is presently available based on the DOCSIS 1.x and DOCSIS 2.0 standards. The DOCSIS 3.0 standard provides this bandwidth increase as well as additional flexibility, where higher data throughput can be obtained by bonding together multiple downstream (DS) channels. This standard calls for the ability to bond any 4 channels in a 64MHz contiguous RF bandwidth. Solutions that allow even more channel bonding and provide more flexibility in the allocated frequency spectrum are preferred. This paper reports an embedded dual-tuner architecture able to select two independent 32MHz frequency bands, allowing for a maximum of 10 demodulated 6MHz Annex B DS channels. In Fig. 6.6.1 the top level block diagram is shown: an external LNA amplifies the RF signal which drives an internal splitter, followed by the two low-IF tuners. Each tuner downconverts 5 DS channels to IF frequencies centered at 0MHz (CH 0), +6MHz (CH +1), +12MHz (CH +2), −6MHz (CH −1) and −12MHz (CH −2). Channels +1 and +2 lie at the images of channels −1 and −2 respectively. Any or all channels can be selected for demodulation by the SoC, up to a maximum of eight. Image rejection is enhanced digitally, taking advantage of the tuner integration into the SoC.

A dual-band tri-mode CDMA IF receiver with programmable channel-match filter

An integrated dual-band tri-mode CDMA IF receiver with programmable channel-match filter is presented. The cascaded VGA and filter chain provides maximum voltage gain of 93 dB with noise figure of <7.5 dB. It also provides >88 dB of gain control range. The IF VCO, which operates at 2/spl times/LO for PCS mode and 4/spl times/LO for AMPS/CDMA mode, achieves -131 dBc/Hz of phase noise at 900 kHz offset with an external tank. An area-efficient combined channel-match filter chain for both CDMA/PCS and AMPS mode is realized by changing the clock frequency of a switched-capacitor filter and by switching-in and -out capacitors for the continuous time and switch-cap filters depending on the mode of operation. The filter chain meets all the blocker requirements for both CDMA/PCS and AMPS modes. Combining the CDMA/PCS and AMPS filter saves 30% die area compared to separate filter chains. The IC is fabricated in Jazzs 35 GHz ft silicon BiCMOS process and packaged into a 48-pin 6 mm/spl times/6 mm land grid array (RF-LGA/spl trade/) chipscale package.

A 28 nm, 475 mW, and 0.4–1.7 GHz Embedded Transceiver Front-End Enabling High-Speed Data Streaming Within Home Cable Networks

A 28 nm CMOS software-defined transceiver (SDTRX) enabling high-speed data (HSD) streaming, including ultra HD TV, within home cable networks is presented. By making efficient use of available cable bandwidth, the SDTRX dynamically handles up to 1024-QAM OFDM-modulated HSD streams. This paper addresses SDTRX system-level design methodology as the key driver in enabling performance optimization for achieving a wide frequency range of operation at lowest power and area consumption. By employing an optimized architecture constructed on available state-of-the-art 28 nm functional building blocks, the monolithic SDTRX consists of a mixer-based harmonic rejection RX with a digital-to-analog converter-based TX and a smart phase-locked loop system. It operates over 0.4–1.7 GHz frequency range while consuming less than 475 mW in half-duplex mode. Moreover, by developing a simple transmitter (TX) to receiver (RX) loopback circuit, the system is enabled to efficiently calibrate TX output power and to remove the need for a dedicated external pin. This low-cost SDTRX is embedded in various 28 nm CMOS multimedia system-on-chip and is, to the authors’ knowledge, the first reported transceiver front-end to enable true HSD streaming within home cable networks.

A 180 mW multistandard TV tuner in 28 nm CMOS

A 28 nm CMOS multistandard TV tuner is presented. A power-efficient RF front end and >80 dB dynamic range ΔΣ ADC, together with a smart AGC algorithm, enable this tuner to achieve 64 dB ATSC A/74 N+6 ACI while dissipating only 180 mW. A baseband resistor weighting harmonic rejection mixer clocked by a 7-13.6 GHz PLL and single-edge-triggered shift registers achieves >58 dB harmonic rejection ratio at frequencies up to 827 MHz.