A robust 2.4 GHz time-of-arrival based ranging system with sub-meter accuracy: feasibility study and realization of low power CMOS receiver

Draadloze sensornetwerken worden meer en meer aangewend om verschillende soorten informatie te verzamelen. De locatie, waar deze informatie verzameld is, is een belangerijke eigenschap en voor sommige toepassingen, zoals het volgen van personen of goederen, zelfs de meest belangrijke en mogelijkmakende factor. Om de positie van een sensor te bepalen, is een technologie nodig die de afstand tot een gekend referentiepunt schat. Door verschillende afstandsmetingen te combineren, is het mogelijk de absolute locatie van de node te berekenen

Inverse Alexander phase detector

An improved bang-bang phase detector (PD) for multi Gb/s clock and data recovery (CDR) circuits is presented. The proposed PD is based on inverting the Alexander PD. In a typical subsampled CDR circuit, this Inverse Alexander PD results in a ten times better bit error rate (BER) compared with the conventional Alexander PD. Additionally, in the case of duty-cycle distorted input data, this Inverse Alexander PD can even reach 20 times better BER compared with the conventional Alexander PD

A digitally controlled threshold adjustment circuit in a 0.13um SiGe BiCMOS technology for receiving multilevel signals up to 80Gbps

In this paper, a high bandwidth digitally controlled threshold adjustment circuit is proposed which can be used for demodulating high-speed multi-level signals. Simulations of the bandwidth are presented together with measurements of the control currents to indicate the threshold adjustment capability. A bandwidth above 80GHz in a 0.13µm SiGe BiCMOS technology and a threshold tunable between ±160mV in steps of 0.6mV is achieved, allowing very precise control of the threshold level. This allows the circuit to accurately position the threshold on the eye-crossing of a high speed multi-level signals. By applying this circuit to demodulate a duobinary signal over a 40GHz channel, a data rate of up to 80Gbps can be achieved

A 16 channel high-voltage driver with 14 bit resolution for driving piezoelectric actuators

A high-voltage, 16 channel driver with a maximum voltage of 72 volt and 14 bit resolution in a high-voltage CMOS (HV-CMOS) process is presented. This design incorporates a 14 bit monotonic by design DAC together with a high-voltage complementary class AB output stage for each channel. All 16 channels are used for driving a piezoelectric actuator within the control loop of a micropositioning system. Since the output voltages are static most of the time, a class AB amplifier is used, implementing voltage feedback to achieve 14 bit accuracy. The output driver consists of a push-pull stage with a built-in output current limitation and high-impedance mode. Also a protection circuit is added which limits the internal current when the output voltage saturates against the high-voltage rail. The 14 bit resolution of each channel is generated with a segmented resistor string DAC which assures monotonic by design behavior by using leapfrogging of the buffers used between segments. A diagonal shuffle layout is used for the resistor strings leading to cancellation of first order process gradients. The dense integration of 16 channels with high peak currents results in crosstalk, countered in this design by using staggered switching and resampling of the output voltages

Solutions for a single carrier 40 Gbit/s downstream long-reach passive optical network

This paper presents a single carrier 40 Gbit/s downstream long-reach passive optical network (LR-PON) topology as candidate for upgrading cur rent f ber infrastructure towards higher data rates. A 100 km LR-PON network was investigated and 2 solutions to overcome chromatic dispersion were proposed. Firstly, a dispersion compensated element is added to compensate the mean length of the feeder f ber. Secondly, an advanced modulation scheme, i.e. 3-level electrical duo-binary is introduced. This scheme has the advantage of allowing lower bandwidth APDs and requires only limited additional electronics. Furthermore, to overcome the inherent discrepancy between aggregated line rate and user rate, and hence the reduced power effciency, the BiPON protocol is added to minimize signal processing at the high line rates

Electronic dispersion precompensation of direct-detected NRZ using analog filtering

We demonstrate (in real-time) electrical dispersion compensation in direct detection links using analog transmit side filtering techniques. By this means, we extend the fiber reach using a low complexity solution while avoiding digital preprocessing and digital-to-analog converters (DACs) which are commonly used nowadays. Modulation is done using an IQ MachZehnder modulator (MZM) which allows straightforward compensation of the complex impulse response caused by chromatic dispersion in the fiber. A SiGe BiCMOS 5-tap analog complex finite impulse response (FIR) filter chip and/or a delay between both driving signals of the MZMs is proposed for the filter implementation. Several link experiments are conducted in C-band where transmission up to 60 km of standard single-mode fiber (SSMF) of direct detected 28Gb/s NRZ/OOK is demonstrated. The presented technique can be used in applications where low power consumption is critical

The truth about 2-level transition elimination in bang-bang PAM-4 CDRs

Reception of 4-level pulse amplitude modulation (PAM-4) requires a clock and data recovery (CDR) circuit, typically implemented by a PLL-like structure. An essential block in such a CDR is the phase detector which should detect whether the recovered clock leads or lags the incoming data edges. In typical implementations an incoming data edge is detected by sensing whether the incoming waveform crosses a data threshold level. However, there is some ambiguity in detecting the incoming data edge because PAM-4 modulation has 3 thresholds. If the waveform crosses multiple threshold levels, the level crossings will occur at different time instants due to the finite rise/fall time of the incoming waveform. In this work, we first analyze qualitatively and quantitatively CDR systems that use one threshold for phase adjustment. Here, eliminating the 2-level transitions decreases the amount of jitter injected by the phase detector. However, the available transitions for phase adjustment are also reduced, which lowers the CDR's robustness. Secondly, for CDR systems using three thresholds, a combination of two techniques: majority voting and elimination of 2-level transitions is investigated. We prove that in this case, the elimination of 2-level transitions is not needed and even gives a worse performance when implemented

Design trade-offs for cost-effective multimode fiber channel equalizers in optical data center applications

A 10-Gb/s transmission over 1-km standard multimode fiber for data center applications is casestudied in terms of the design considerations for low-complexity and cost-effective equalizers which can increase the reach of multimode fiber links