PAC2013 - List of Authors (Hrovatin, R.)

Paper	Title	Page
THPAC04	Beam Position Electronics Based on System on Chip Platform	1145
	M. Cargnelutti, R. Hrovatin, G. Jug I-Tech, Solkan, Slovenia
	With the advances in system-on-chip (SoC) technology, the CPU and FPGA are today enclosed in the same device. This enables high-speed processing, inherent fast communication and memory sharing between the two entities. However, dedicated tools for implementation are needed as the CPU and FPGA functionalities cannot easily be decoupled. We used the advantages of the new architecture in the development of a booster BPM electronics. Its requirements are relaxed compared to up-to-now Libera beam position monitors. Proper design of the RF part of the instrument is still a challenge. Furthermore, with optimized FPGA design we target low overall power consumption so that the instrument can be cooled passively.

THPMA04	Next Generation CW Reference Clock Transfer System with Femtosecond Stability	1358
	P.L. Lemut, R. Hrovatin, P. Orel, S. Zorzut I-Tech, Solkan, Slovenia S. Hunziker, V. Schlott PSI, Villigen PSI, Switzerland
	Present and future fourth generation light sources, like the Swiss FEL, are placing strict requirements on today’s CW reference clock transfer systems. Both the added jitter and the long-term stability criteria need to be in the range of a few femtoseconds. In order to meet these requirements the existing Libera Sync CW transfer system has been redesigned. All of the aspects of the system design have been revisited and improved, from new measuring methods and better evaluation of components to careful pre-design testing and simulation. New fiber link topology, new approaches in thermal stabilization, improved power supply distribution and interconnection of carefully selected electrical and state-of-the-art optical components led to a significant reduction in added jitter and excellent long-term stability of the system. Measurements repeatedly show the jitter performance to be below 6 fs, integrated over the frequency range of 10 Hz to 10 MHz. Preliminary measurements of the long-term stability place the system in the range of a few tens of femtoseconds of drift per day.

Paper

Title

Page

Beam Position Electronics Based on System on Chip Platform

1145

M. Cargnelutti, R. Hrovatin, G. Jug
I-Tech, Solkan, Slovenia

With the advances in system-on-chip (SoC) technology, the CPU and FPGA are today enclosed in the same device. This enables high-speed processing, inherent fast communication and memory sharing between the two entities. However, dedicated tools for implementation are needed as the CPU and FPGA functionalities cannot easily be decoupled. We used the advantages of the new architecture in the development of a booster BPM electronics. Its requirements are relaxed compared to up-to-now Libera beam position monitors. Proper design of the RF part of the instrument is still a challenge. Furthermore, with optimized FPGA design we target low overall power consumption so that the instrument can be cooled passively.

THPMA04

Next Generation CW Reference Clock Transfer System with Femtosecond Stability

1358

P.L. Lemut, R. Hrovatin, P. Orel, S. Zorzut
I-Tech, Solkan, Slovenia
S. Hunziker, V. Schlott
PSI, Villigen PSI, Switzerland

Present and future fourth generation light sources, like the Swiss FEL, are placing strict requirements on today’s CW reference clock transfer systems. Both the added jitter and the long-term stability criteria need to be in the range of a few femtoseconds. In order to meet these requirements the existing Libera Sync CW transfer system has been redesigned. All of the aspects of the system design have been revisited and improved, from new measuring methods and better evaluation of components to careful pre-design testing and simulation. New fiber link topology, new approaches in thermal stabilization, improved power supply distribution and interconnection of carefully selected electrical and state-of-the-art optical components led to a significant reduction in added jitter and excellent long-term stability of the system. Measurements repeatedly show the jitter performance to be below 6 fs, integrated over the frequency range of 10 Hz to 10 MHz. Preliminary measurements of the long-term stability place the system in the range of a few tens of femtoseconds of drift per day.