In the low-level RF control field,ADC acquisition accuracy and noise set the boundary of our control ability,making it important to develop low-noise acquisition systems.From the design to test stage,all the noise ter...In the low-level RF control field,ADC acquisition accuracy and noise set the boundary of our control ability,making it important to develop low-noise acquisition systems.From the design to test stage,all the noise terms should be understood and characterized.The specific need addressed here is the precision acquisition system for the second Linac Coherent Light Source(LCLS-Ⅱ),led by SLAC National Accelerator Laboratory.Test circuit boards for the LTC2174 and AD9268 ADCs are designed and fabricated by LBNL.An ADC test framework based on FPGA evaluation board to assess performance has been developed.The ADC test framework includes both DSP(Digital Signal Processing) firmware and processing software.It is useful for low-level RF control and other synchronization projects.Investigating the clock jitter between two channels give us an understanding of that noise source.Working with the test framework,the raw ADC data are transferred to a computer through a Gigabit Ethernet interface.Then short-term error signal can be calculated based on a sine wave fit.By changing low-pass filter bandwidth,relative long-term performance can also be obtained.Amplitude jitter and differential phase jitter are the key issues for ADCs.This paper will report the test results for LTC2174 and AD9268 chips.The integral amplitude jitter is smaller than 0.003%,and the integral phase noise is smaller than 0.0015°(measured at 47 MHz RF,100 MHz clock,bandwidth 1 Hz to 100 kHz) for both ADC chips.展开更多
Coherent pulse stacking(CPS) is a new time-domain coherent addition technique that stacks several optical pulses into a single output pulse, enabling high pulse energy and high average power. A Z-domain model target...Coherent pulse stacking(CPS) is a new time-domain coherent addition technique that stacks several optical pulses into a single output pulse, enabling high pulse energy and high average power. A Z-domain model targeting the pulsed laser is assembled to describe the optical interference process. An algorithm, extracting the cavity phase and pulse phases from limited data, where only the pulse intensity is available, is developed to diagnose optical cavity resonators. We also implement the algorithm on the cascaded system of multiple optical cavities,achieving phase errors less than 1.0°(root mean square), which could ensure the stability of CPS.展开更多
基金supported by the US.Department of Energy(DEAC02-05CH11231)the China Scholarship Council
文摘In the low-level RF control field,ADC acquisition accuracy and noise set the boundary of our control ability,making it important to develop low-noise acquisition systems.From the design to test stage,all the noise terms should be understood and characterized.The specific need addressed here is the precision acquisition system for the second Linac Coherent Light Source(LCLS-Ⅱ),led by SLAC National Accelerator Laboratory.Test circuit boards for the LTC2174 and AD9268 ADCs are designed and fabricated by LBNL.An ADC test framework based on FPGA evaluation board to assess performance has been developed.The ADC test framework includes both DSP(Digital Signal Processing) firmware and processing software.It is useful for low-level RF control and other synchronization projects.Investigating the clock jitter between two channels give us an understanding of that noise source.Working with the test framework,the raw ADC data are transferred to a computer through a Gigabit Ethernet interface.Then short-term error signal can be calculated based on a sine wave fit.By changing low-pass filter bandwidth,relative long-term performance can also be obtained.Amplitude jitter and differential phase jitter are the key issues for ADCs.This paper will report the test results for LTC2174 and AD9268 chips.The integral amplitude jitter is smaller than 0.003%,and the integral phase noise is smaller than 0.0015°(measured at 47 MHz RF,100 MHz clock,bandwidth 1 Hz to 100 kHz) for both ADC chips.
基金supported by the Director,Office of Science,Office of High Energy Physics,of the U.S.Department of Energy under Contract No.DE-AC02-05CH11231by the National Natural Science Foundation of China under Grant No.11475097
文摘Coherent pulse stacking(CPS) is a new time-domain coherent addition technique that stacks several optical pulses into a single output pulse, enabling high pulse energy and high average power. A Z-domain model targeting the pulsed laser is assembled to describe the optical interference process. An algorithm, extracting the cavity phase and pulse phases from limited data, where only the pulse intensity is available, is developed to diagnose optical cavity resonators. We also implement the algorithm on the cascaded system of multiple optical cavities,achieving phase errors less than 1.0°(root mean square), which could ensure the stability of CPS.
