PVT-Robust Ultra-Low-Jitter Clock Multipliers Using an Injection-Locking Technique

Department of Electrical EngineeringThis thesis presents process-voltage-temperature (PVT)-robust ultra-low-jitter clock multipliers using an injection-locking technique. First, an injection-locked clock multiplier (ILCM) using a two-phase PVT-calibrator is proposed. The proposed PVT-calibration technique is based on the dual-loop architecture which consists of a main-voltage-controlled oscillator (VCO) and a replica-VCO. While the main-VCO is injection-locked and generates the precise target frequency, the real-time frequency variation of the replica-VCO can be monitored by the PVT-calibrator which adjusts the control voltage shared by the two identical VCOs. Using the two-phase calibration technique, the tradeoff between the calibration resolution and the lock time was removed. The proposed ILCM, fabricated in the 65-nm CMOS process, generated five different reference frequencies, i.e., 19.2, 28.8, 48.0, 57.6, and 96.0 MHz with a 19.2 MHz external clock. When injection-locked, the integrated jitter from 1 kHz to 10 MHz of the 96-MHz signal was 1.69 ps. The proposed PVT-calibrator restricted the phase noise degradation over the temperature range of 30 to 80 ??C to less than 0.5 dB. Second, a fractional-resolution ILCM using a delay-locked-loop (DLL)-based PVT-calibrator is proposed. In this architecture, the ring-type VCO and the voltage-controlled delay line (VCDL) of the DLL consist of identical delay cells, and they share the same control voltage. Thus, by changing the ratio between the numbers of stages of the VCDL and the VCO, the frequency of the VCO can be calibrated at a target frequency, a non-integer times the reference frequency. The proposed ILCM, designed in the 65-nm CMOS process, generated output frequencies that range from 1.2 to 2.0 GHz with a frequency resolution of 40 MHz with a 400-MHz reference clock. When injection-locked, the integrated jitter from 1 kHz to 40 MHz of the 1.6-GHz signal was 440 fs. The proposed DLL-based PVT-calibrator restricted the degradations of phase noise and jitter over the temperature and the supply variations to less than 0.7 dB and 20%, respectively. Both architectures presented in this thesis can overcome real-time frequency drifts as well as static process variationsthus, excellent jitter performance can be sustained during any environmental variations.ope

A Low-Power BFSK/OOK Transmitter for Wireless Sensors

In recent years, significant improvements in semiconductor technology have allowed consistent development of wireless chipsets in terms of functionality and form factor. This has opened up a broad range of applications for implantable wireless sensors and telemetry devices in multiple categories, such as military, industrial, and medical uses. The nature of these applications often requires the wireless sensors to be low-weight and energy-efficient to achieve long battery life. Among the various functions of these sensors, the communication block, used to transmit the gathered data, is typically the most power-hungry block. In typical wireless sensor networks, transmission range is below 10 meters and required radiated power is below 1 milliwatt. In such cases, power consumption of the frequency-synthesis circuits prior to the power amplifier of the transmitter becomes significant. Reducing this power consumption is currently the focus of various research endeavors. A popular method of achieving this goal is using a direct-modulation transmitter where the generated carrier is directly modulated with baseband data using simple modulation schemes. Among the different variations of direct-modulation transmitters, transmitters using unlocked digitally-controlled oscillators and transmitters with injection or resonator-locked oscillators are widely investigated because of their simple structure. These transmitters can achieve low-power and stable operation either with the help of recalibration or by sacrificing tuning capability. In contrast, phase-locked-loop-based (PLL) transmitters are less researched. The PLL uses a feedback loop to lock the carrier to a reference frequency with a programmable ratio and thus achieves good frequency stability and convenient tunability. This work focuses on PLL-based transmitters. The initial goal of this work is to reduce the power consumption of the oscillator and frequency divider, the two most power-consuming blocks in a PLL. Novel topologies for these two blocks are proposed which achieve ultra-low-power operation. Along with measured performance, mathematical analysis to derive rule-of-thumb design approaches are presented. Finally, the full transmitter is implemented using these blocks in a 130 nanometer CMOS process and is successfully tested for low-power operation

Self-Calibrated, Low-Jitter and Low-Reference-Spur Injection-Locked Clock Multipliers

Department of Electrical EngineeringThis dissertation focuses primarily on the design of calibrators for the injection-locked clock multiplier (ILCM). ILCMs have advantage to achieve an excellent jitter performance at low cost, in terms of area and power consumption. The wide loop bandwidth (BW) of the injection technique could reject the noise of voltage-controlled oscillator (VCO), making it thus suitable for the rejection of poor noise of a ring-VCO and a high frequency LC-VCO. However, it is difficult to use without calibrators because of its sensitiveness in process-voltage-temperature (PVT) variations. In Chapter 2, conventional frequency calibrators are introduced and discussed. This dissertation introduces two types of calibrators for low-power high-frequency LC-VCO-based ILFMs in Chapter 3 and Chapter 4 and high-performance ring-VCO-based ILCM in Chapter 5. First, Chapter 3 presents a low power and compact area LC-tank-based frequency multiplier. In the proposed architecture, the input signals have a pulsed waveform that involves many high-order harmonics. Using an LC-tank that amplifies only the target harmonic component, while suppressing others, the output signal at the target frequency can be obtained. Since the core current flows for a very short duration, due to the pulsed input signals, the average power consumption can be dramatically reduced. Effective removal of spurious tones due to the damping of the signal is achieved using a limiting amplifier. In this work, a prototype frequency tripler using the proposed architecture was designed in a 65 nm CMOS process. The power consumption was 950 ??W, and the active area was 0.08 mm2. At a 3.12 GHz frequency, the phase noise degradation with respect to the theoretical bound was less than 0.5 dB. Second, Chapter 4 presents an ultra-low-phase-noise ILFM for millimeter wave (mm-wave) fifth-generation (5G) transceivers. Using an ultra-low-power frequency-tracking loop (FTL), the proposed ILFM is able to correct the frequency drifts of the quadrature voltage-controlled oscillator of the ILFM in a real-time fashion. Since the FTL is monitoring the averages of phase deviations rather than detecting or sampling the instantaneous values, it requires only 600??W to continue to calibrate the ILFM that generates an mm-wave signal with an output frequency from 27 to 30 GHz. The proposed ILFM was fabricated in a 65-nm CMOS process. The 10-MHz phase noise of the 29.25-GHz output signal was ???129.7 dBc/Hz, and its variations across temperatures and supply voltages were less than 2 dB. The integrated phase noise from 1 kHz to 100 MHz and the rms jitter were???39.1 dBc and 86 fs, respectively. Third, Chapter 5 presents a low-jitter, low-reference-spur ring voltage-controlled oscillator (ring VCO)-based ILCM. Since the proposed triple-point frequency/phase/slope calibrator (TP-FPSC) can accurately remove the three root causes of the frequency errors of ILCMs (i.e., frequency drift, phase offset, and slope modulation), the ILCM of this work is able to achieve a low-level reference spur. In addition, the calibrating loop for the frequency drift of the TP-FPSC offers an additional suppression to the in-band phase noise of the output signal. This capability of the TP-FPSC and the naturally wide bandwidth of the injection-locking mechanism allows the ILCM to achieve a very low RMS jitter. The ILCM was fabricated in a 65-nm CMOS technology. The measured reference spur and RMS jitter were ???72 dBc and 140 fs, respectively, both of which are the best among the state-of-the-art ILCMs. The active silicon area was 0.055 mm2, and the power consumption was 11.0 mW.clos

Design of High-Speed SerDes Transceiver for Chip-to-Chip Communications in CMOS Process

With the continuous increase of on-chip computation capacities and exponential growth of data-intensive applications, the high-speed data transmission through serial links has become the backbone for modern communication systems. To satisfy the massive data-exchanging requirement, the data rate of such serial links has been updated from several Gb/s to tens of Gb/s. Currently, the commercial standards such as Ethernet 400GbE, InfiniBand high data rate (HDR), and common electrical interface (CEI)-56G has been developing towards 40+ Gb/s. As the core component within these links, the transceiver chipset plays a fundamental role in balancing the operation speed, power consumption, area occupation, and operation range. Meanwhile, the CMOS process has become the dominant technology in modern transceiver chip fabrications due to its large-scale digital integration capability and aggressive pricing advantage. This research aims to explore advanced techniques that are capable of exploiting the maximum operation speed of the CMOS process, and hence provides potential solutions for 40+ Gb/s CMOS transceiver designs. The major contributions are summarized as follows. A low jitter ring-oscillator-based injection-locked clock multiplier (RILCM) with a hybrid frequency tracking loop that consists of a traditional phase-locked loop (PLL), a timing-adjusted loop, and a loop selection state-machine is implemented in 65-nm C-MOS process. In the ring voltage-controlled oscillator, a full-swing pseudo-differential delay cell is proposed to lower the device noise to phase noise conversion. To obtain high operation speed and high detection accuracy, a compact timing-adjusted phase detector tightly combined with a well-matched charge pump is designed. Meanwhile, a lock-loss detection and lock recovery is devised to endow the RILCM with a similar lock-acquisition ability as conventional PLL, thus excluding the initial frequency set- I up aid and preventing the potential lock-loss risk. The experimental results show that the figure-of-merit of the designed RILCM reaches -247.3 dB, which is better than previous RILCMs and even comparable to the large-area LC-ILCMs. The transmitter (TX) and receiver (RX) chips are separately designed and fab- ricated in 65-nm CMOS process. The transmitter chip employs a quarter-rate multi-multiplexer (MUX)-based 4-tap feed-forward equalizer (FFE) to pre-distort the output. To increase the maximum operating speed, a bandwidth-enhanced 4:1 MUX with the capability of eliminating charge-sharing effect is proposed. To produce the quarter-rate parallel data streams with appropriate delays, a compact latch array associated with an interleaved-retiming technique is designed. The receiver chip employs a two-stage continuous-time linear equalizer (CTLE) as the analog front-end and integrates an improved clock data recovery to extract the sampling clocks and retime the incoming data. To automatically balance the jitter tracking and jitter suppression, passive low-pass filters with adaptively-adjusted bandwidth are introduced into the data-sampling path. To optimize the linearity of the phase interpolation, a time-averaging-based compensating phase interpolator is proposed. For equalization, a combined TX-FFE and RX-CTLE is applied to compensate for the channel loss, where a low-cost edge-data correlation-based sign zero-forcing adaptation algorithm is proposed to automatically adjust the TX-FFE’s tap weights. Measurement results show that the fabricated transmitter/receiver chipset can deliver 40 Gb/s random data at a bit error rate of 16 dB loss at the half-baud frequency, while consuming a total power of 370 mW