Title: Online%20Models%20for%20PEP-II
1Online Models for PEP-II Status
- brief review of PEP modeling
- fully coupled normal form optics representation
- Orbit Response Matrix (ORM) model calibration
fudge factors for quadrupole strengths - continuing work
2PEP Online Modeling Procedure
- prepare input files for MAD
- read reference input files
- set magnets to configuration file values
- apply ORM-derived fudge factors to quadrupole
strengths - run MAD
- use XCORs and YCORs to steer to measured absolute
orbit - compute effective transfer matrices (RMATs)
- generate model files for MCC
- extract coupled lattice functions from RMATs
3PEP Online Modeling Process
MCC (VMS)
pepoptics (linux)
Input Files
AT
11
7
8
10
SCP
Matlab
1
5
2
6
9
SCP, SSH
MAD updated to v 8.51/15
4
DIMAD not used anymore
3
4Lattice parameters in highly coupled systems
- MAD (v 8.51/15-SLAC) has been modified to output
effective transfer matrices (first order
expansion about the closed orbit includes feed
down effects from sextupoles) - Andy Wolskis normal form analysis1 is used to
extract coupled lattice parameters from the
transfer matrices - 10 coupled lattice parameters (µ, ß, a, ?, ?? for
modes 1 2) and 8 elements of the normalizing
transformation (n13, n14, n23, n24, n31, n32,
n41, n42) at each element are returned to be
loaded into the MCC database
1See http//www-library.lbl.gov/docs/LBNL/547/74/P
DF/LBNL-54774.pdf
5ORM analysis LER
- ORM analysis begins with the config lattice
(actual magnet strengths, steered to the measured
absolute orbit) - only quadrupole strength errors are fitted (no
sextupole strength errors) - errors are assigned to quadrupole families (power
supplies) - sextupole feed down effects are not explicitly
fitted (even though they are important for LER)
the assumption is that the BPMs are correct (BBA)
and that steering to the measured orbit is
sufficient to model the feed down effects - fudge factors are computed by comparing the
fitted quadrupole strengths with their config
values normal quadrupole fudge factors are
multiplicative skew quadrupole fudge factors are
additive (since most skew quads should nominally
be at or near zero) - the actual ORM analysis for LER is performed by
Cristoph Steier (LBNL) using the Matlab-based
version of the LOCO program
See PTs presentation on Recent ORM Results for
further details
6ORM-derived fudge factors LER (1)
ORM data taken on December 11, 2003
7ORM-derived fudge factors LER (2)
fudged
8ORM-derived fudge factors LER (3)
unfudged
fudged
fudged
unfudged
9ORM-derived fudge factors LER (4)
10ORM-derived fudge factors HER (1)
- normal quadrupoles
- skew quadrupoles
ORM data taken on June 10, 2004
11ORM-derived fudge factors HER (2)
fudged
unfudged
fudged
unfudged
12ORM-derived fudge factors HER (3)
fudged
unfudged
fudged
unfudged
13ORM-derived fudge factors HER (4)
14Continuing work
- steering to absolute orbits when generating the
model in order to properly account for sextupole
feed down effects requires accurate knowledge of
BPM offsets ? BBA1 many offsets for both HER and
LER have been measured and are being routinely
used to correct measured orbits LER BBA is
ongoing (more on this in a minute ) - continue to fine tune the ORM analysis setup to
avoid degeneracy in the variables - fudge factors for individual magnets (?)
- develop more robust steering algorithms for model
generation to take into account bad BPMs
(especially for LER) - create fudged design configs move toward
design optics in both rings - participate in the ILC design
1See Tonee Smiths presentation on New BBA
Hardware for further details
15BBA at PEP-II Status
- large unexplained LER BPM offsets from BBA ?
uncoupled analysis of orbits in a highly coupled
machine - new analysis algorithm
- BPM offsets revisited
16Unexplained large (1 cm) LER BPM offsets from BBA
from Marc Ross summary at April MAC
17BBA Analysis
- orbit fitting lies at the heart of our BBA
analysis algorithm - move the beam in a quadrupole (using a closed
bump), change the strength of the quadrupole, and
look at the orbit change - if the orbit doesnt change when the quadrupole
strength is changed, the beam is passing through
the center of the quadrupole the reading on a
nearby BPM under these conditions is the BPM
offset - if youre moving the beam in X, you look at the
change in the X orbit, which should be
proportional to the distance (in X) between the
beam and the quadrupole center in an uncoupled
ring - if youre moving the beam in X, and the beam
happens to be offset in Y to begin with, the
previous statement remains true in an uncoupled
ring - if youre moving the beam in X, and the beam
happens to be offset in Y, and your ring is
highly coupled, you have to pay attention to
whats happening in both planes simultaneously
(well duh)
18QDBM3 simulated X data -10 mm Y offset uncoupled
orbit fit
?x (mm)
blue o MAD red - - orbit fit
19(No Transcript)
20BBA Analysis
21Coupled BBA Analysis Algorithm
- Change in closed orbit (?xco,?yco) due to a
change in strength (K?K(1)) of a - misaligned quadrupole (xbq,ybq)
- includes closed orbit effects of ?K (both kick
and position shift) - includes optics effects of ?K (change in closed
orbit response matrix) - fits both planes simultaneously, including any
known coupling
A. Wolski and F. Zimmerman, Closed Orbit
Response to Quadrupole Strength Variation,
http//www-library.lbl.gov/docs/LBNL/543/60/PDF/LB
NL-54360.pdf
22QDBM3 simulated X data -10 mm Y offset coupled
orbit fit
?x (mm)
?y (mm)
23LER BPM X Offsets Then and Now
24LER BPM Y Offsets Then and Now
25Acknowledgements thanks!