Betatron tune Measurement

Similar documents
Lattice Design for PRISM-FFAG. A. Sato Osaka University for the PRISM working group

DEVELOPMENT OF CAPACITIVE LINEAR-CUT BEAM POSITION MONITOR FOR HEAVY-ION SYNCHROTRON OF KHIMA PROJECT

The impedance budget of the CERN Proton Synchrotron (PS)

AC Dispersion Measurement. David Rubin Cornell Laboratory for Accelerator-Based Sciences and Education

EMMA the World's First Non-Scaling FFAG Accelerator

Lawrence Berkeley Laboratory UNIVERSITY OF CALIFORNIA

Status of Proton Beam Commissioning at MedAustron Ion Beam Therapy Center

EFFECTS OF FRINGE FIELDS AND INSERTION DEVICES REVEALED THROUGH EXPERIMENTAL FREQUENCY MAP ANALYSIS*

FAST RF KICKER DESIGN

KEK Digital Accelerator and Its Beam Commissioning

PINGER MAGNET SYSTEM FOR THE ALBA SYNCHROTRON LIGHT SOURCE

Recent studies of the electron cloud-induced beam instability at the Los Alamos PSR

LHC TRANSVERSE FEEDBACK SYSTEM: FIRST RESULTS OF COMMISSIONING. V.M. Zhabitsky XXI Russian Particle Accelerator Conference

Multi-bunch feedback systems

Trajectory Measurements in the DAΦNE Transfer Line using log Amplifier

Multi-bunch Feedback Systems

Modeling and Measurement of Amplitude Dependent Tune Shifts in CESR

PArticles in an accelerator generally oscillate in directions

Longitudinal bunch shape Overview of processing electronics for Beam Position Monitor (BPM) Measurements:

REVIEW OF FAST BEAM CHOPPING F. Caspers CERN AB-RF-FB

Bunch-by-bunch studies at DELTA

TURN-BY-TURN BPM SYSTEM USING COAXIAL SWITCHES AND ARM MICROCONTROLLER AT UVSOR

Tutorial on Design of RF system for Indus Accelerator. Maherdra Lad Head, Radio Frequency Systems Division RRCAT, Indore

JEDI. Status of the commissioning of the waveguide RF Wien Filter

Beam Position Monitor with HOM couplers

Fast Kickers at DESY

Dark Current Kicker Studies at FLASH

Proceedings of the Twelfth International Conference on Cyclotrons and their Applications, Berlin, Germany BEAM DIAGNOSTICS AT THE JINR PHASOTRON

Digital Signal processing in Beam Diagnostics Lecture 2

SOLEIL Libera Performance

Plan for Accelerator Beam Study Towards J-PARC Muon Project. Koji YOSHIMURA (KEK) for KEK Muon Working Group at NuFACT08 July 2nd, 2008

ALS Beam Instrumentation Beam Position Monitoring Jim Hinkson March, 2000

Acceleration of High-Intensity Protons in the J-PARC Synchrotrons. KEK/J-PARC M. Yoshii

A Novel RF-ExB Spin Manipulator at COSY Contribution to SPIN2014

Design of ESS-Bilbao RFQ Linear Accelerator

Spin Manipulation with an RF Wien-Filter at COSY PSTP Workshop 2015

Beam Bunches Kicker Structure. Timing & Control. Downsampler A/D DSP. Farm of Digital Signal Processors. Master Oscillator Phase-locked

Beam Infrared Detection with Resolution in Time

Slide Title. Bulleted Text

Towards an RF Wien-Filter for EDM Searches in Storage Rings

Accelerator Complex U70 of IHEP-Protvino: Status and Upgrade Plans

An RF Wien Filter as Spin Manipulator MT Student Retreat 2015

Analogue electronics for BPMs at GSI - Performance and limitations

Beam Control: Timing, Protection, Database and Application Software

Multi-bunch Feedback Systems

Analysis of Phase Space Matching with RF Quadrupole

Suppression of Vertical Oscillation and Observation of Flux Improvement during Top-up Injection at PLS-II

Re-commissioning the Recycler Storage Ring at Fermilab

cyclotron RF systems sb/cas10061/1

Proton beam for UCN. UCN TAC-Meeting, May 12-13, 2005 Urs Rohrer, beam line physicist

Mul$- bunch accelera$on in FFAG. Takeichiro Yokoi(JAI)

SIGNAL ELECTRIC FIELD MAGNETIC FIELD # 1 (#2) #3 (# 4) WAVEGUIDE VACUUM CHAMBER BEAM PIPE VACUUM CHAMBER

FLASH Operation at DESY From a Test Accelerator to a User Facility

7.2 Fast-response beam loss monitor

National Accelerator Laboratory

arxiv: v3 [physics.acc-ph] 4 Aug 2017

Measurement Setup for Bunched Beam Echoes in the HERA Proton Storage Ring

Transverse Wakefields and Alignment of the LCLS-II Kicker and Septum Magnets

Beam Diagnostics, Low Level RF and Feedback for Room Temperature FELs. Josef Frisch Pohang, March 14, 2011

Recent Experimental Studies of the Electron Cloud at the Los Alamos PSR

MEASURES TO REDUCE THE IMPEDANCE OF PARASITIC RESONANT MODES IN THE DAΦNE VACUUM CHAMBER

System Integration of the TPS. J.R. Chen NSRRC, Hsinchu

Electron cloud effects, codes & simulations. K. Ohmi (KEK) ICAP12, Aug, 2012 Rostock

ANALYZING GIGAHERTZ BUNCH LENGTH INSTABILITIES WITH A DIGITAL SIGNAL PROCESSOR*

HITACHI Proton Therapy System with Spot Scanning

Worksheet for the afternoon course Tune measurements simulated with a DSP card

MD 2485: Active halo control using narrowband and colored noise excitations

Attosecond Diagnostics of Muti GeV Electron Beams Using W Band Deflectors

A Synchrotron Phase Detector for the Fermilab Booster

Linear Particle Accelerator Control Performance

Advanced Photon Source Monopulse rf Beam Position Monitor Front-End Upgrade*

ION PRODUCTION AND RF GENERATION IN THE DARHT-II BEAM DUMP

Using Higher Order Modes in the Superconducting TESLA Cavities for Diagnostics at DESY

THE LINAC LASER NOTCHER FOR THE FERMILAB BOOSTER*

EMMA Project Status and Overview

FAST KICKERS LNF-INFN

Optical Pumping Control Unit

Nonintercepting Diagnostics for Transverse Beam Properties: from Rings to ERLs

A high resolution bunch arrival time monitor system for FLASH / XFEL

New apparatus for precise synchronous phase shift measurements in storage rings 1

Single Bunch Impurity Measurement at SPring-8 8 Storage Ring

Accurate Electromagnetic Simulation and Design of Cyclotron Cavity Masoumeh Mohamadian, Hossein Afarideh, and Mitra Ghergherehchi

DQW HOM Coupler for LHC

3.0 Apparatus. 3.1 Excitation System

Chapter 11. Beam Instrumentation Beam Position Monitor (BPM) Pickup unit

Beam Loss monitoring R&D. Arden Warner Fermilab MPS2014 Workshop March 5-6, 2014

Specification of the kicker Measurement of the magnetic field inside the kicker Optimisation of the kicker impedance to 50 Status and picture of the

MULTIBUNCH INSTABILITIES AND CURES

Performance Evaluation of the Upgraded BAMs at FLASH

Project X Cavity RF and mechanical design. T. Khabiboulline, FNAL/TD/SRF

HIGHER ORDER MODES FOR BEAM DIAGNOSTICS IN THIRD HARMONIC 3.9 GHZ ACCELERATING MODULES *

OPTIMIZED MAGNET FOR A 250 MEV PROTON RADIOTHERAPY CYCLOTRON

CHAPTER 6 BOOSTER RF SYSTEMS

PHY3902 PHY3904. Nuclear magnetic resonance Laboratory Protocol

Bunch-by-Bunch Broadband Feedback for the ESRF

COMMISSIONING STATUS AND FURTHER DEVELOPMENT OF THE NOVOSIBIRSK MULTITURN ERL*

Beam Position Monitoring System In Accelerators

STABILITY CONSIDERATIONS

SIMULATION CODES. Proceedings of IBIC2014, Monterey, CA, USA

EuroTeV High Bandwidth Wall Current Monitor. Alessandro D Elia AB-BI-PI 1-1 -

Transcription:

Betatron tune Measurement Tom UESUGI, Y. Kuriyama, Y. Ishi FFA school, Sep. 8-9, Osaka, 218

CONTENTS Betatron oscillation and tune How to measure tunes KURNS FFAG, Diagnostics

BETATRON OSCILLATION AND TUNE

You know what is betatron oscillation A particle in a circular accelerator affects focusing forces by gradient field, and oscillates in transverse directions at closed orbit. = betatron oscillation Its frequency depends on field gradient. Horizontal ( f x ) and vertical ( f y ) frequencies are different, in general.

Betatron tunes are the frequencies of the betatron oscillations, divided by the revolution frequency. fx f y ( Q x,q y )=, f rev f rev It is very important parameters in a circular accelerator. Beams tend to be lost if the tunes satisfy the resonance condition; `Q x + mq y = n (`, m, n = small integers) Vertical tune Qy 1.5 1.45 1.4 1.35 1.3 1.25 1.2 1.15 1.1 1.5 1 3.5 3.55 3.6 3.65 3.7 3.75 3.8 3.85 3.9 3.95 4 Horizontal tune Qx

HOW TO MEASURE TUNES keywords Beam position monitor Coherent betatron oscillations Spectrum with betatron sidebands

Electro-static beam position monitor is composed of a electrode installed in the vacuum chamber. When a charged particle beam pass through, longitudinal charge distribution can be detected. Bunch monitor Positive charge of the beam Negative image charge Beam

Electro-static beam position monitor is sensitive to the beam center position. Positive charge of the beam Negative image charge Beam

Coherent oscillations are necessary to measure the frequency by BPM Beam center BPM can detect only the position of beam center. It needs to excite coherent oscillations to observe the betatron oscillation.

How to excite coherent oscillations (1) Strong pulse kick Coherent oscillations can be observed, if the kick angle is large enough. x amplitude ' x = q B` p = B`.48 [T m] ( 11 MeV proton ) In KURNS FFAG, extraction kicker is available, only around the extraction orbit. = B` 1.48 [T m] ( 1 MeV proton ) (2) Rf shaker Applies transverse field for long duration time. Amplitude of coherent oscillations are resonantly grow up, if the shaker frequency is close to the betatron frequency.

Strong pulse kick Detect coherent oscillations Measure the frequency Rf shaker tuning its frequency Detect coherent oscillations Measure the frequency Beam loss

Signal from Beam Position Monitor T

Signal from Beam Position Monitor Short bunch approximation V (t) = 1X V (t nt ) Output Time n= T V Revolution time Proportional to beam intensity In presence of coherent betatron oscillations Output V (t) = 1X (V + V cos! t) (t nt ) n= AM factor Time V! Betatron amplitude Betatron (angular) frequency

Spectrum! 2! 3! 4! Output Output Time Frequency V (t) = T V 1X V (t nt ) n= Revolution time Proportional to beam intensity Z Ṽ (!) = 1 X n= V (t nt )exp(i!t)dt X 1 = V exp(im!t ) m= 1 X 1 =! V (! n! ) n= 1

Spectrum ( with betatron oscillation )! 2! 3! 4! Output Output V (t) = 1X (V + V cos! t) (t nt ) n= Ṽ (!) = Z 1 X n= =! V 1 X n= 1 =! V 1 X n= 1 Time Time AM (V + V cos! t) (t nt )exp(i!t)dt (! n! ) + V 2 (! n! ) +! V 2 1X m= 1 1X m= 1 V! T V! = 2 T Frequency e im(!+! )t im(!! + e )t Betatron amplitude Betatron (angular) frequency Revolution time Proportional to beam intensity [! (m!! )] + [! (m! +! )]

Ambiguity of measured tune =! V 1 X n= 1 Q=.32 5 Q=1.32 (! n! ) +! V 2 Q=.68 5 Q=1.68 1X m= 1 [! (m!! )] + [! (m! +! )]! = 8 >< >: m! m! +! =! (m + Q) m!! =! (m Q) m =, ±1, ±2, ±3, Signal are the same for these Q values 5 5 Q=2.32 Q=2.68 You must choose one of them, knowing designed tune value. 5 5

KURNS FFAG, DIAGNOSTICS keywords Beam position monitor Rf shaker

KURNS FFAG Main Ring

KURNS FFAG Main Ring

Main Parameters Particle Cell Orbit radius Revolution Proton ( H- beams are injected) Scaling FFAG, Radial DFD x 12, k=7.6 4.6-5.3 m 1. 6-4.3 MHz Designed tune ~( 3.7, 1.4 )

BPM in KURNS FFAG for vertical position pickup for horizontal position pickup Wide electrode Triangular electrodes Beam 1 pf Beam 1 pf 1 M 46 db to control room 1 M 46 db

Shaker in KURNS FFAG VsinWt charged-particle beam for Vertical excitation Same as the vertical BPM VsinWt for Horizontal excitation Remote controlled in horizontal direction charged-particle beam

Positions of the monitors and shakers Beam position monitor Rf shaker

Summary Accelerator room Control room Shaker Amplifier Signal generator Amplitude Frequency Burst length Trigger time Lets go to the control room! Oscilloscope Coherent oscillations Beam loss Beam position monitor Amp Spectrum analyzer Sideband frequency

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback