Paper 
Title 
Page 
TUPS073 
TopUp Safety Simulations for the TPS Storage Ring 
1707 

 H.J. Tsai, C.C. Chiang, P.J. Chou, C.C. Kuo
NSRRC, Hsinchu, Taiwan



TPS is a 3 GeV third generation light source and operates in the topup injection scheme. During the topup injection, the beamline photon shutters are always open. To ensure the radiation safety of beamline experiments, we studied the possible particle leakage to ID and neighboring bending beamlines. The effects of errors on magnets and beam chamber alignments are investigated.



WEPC033 
Decoupling Problem of Weakly Linear Coupled Double Minibetay Lattice of TPS Storage Ring 
2076 

 H.P. Chang, C.C. Chiang, M.S. Chiu
NSRRC, Hsinchu, Taiwan



Three double minibetay (DMBy) lattice design of the TPS storage ring is in progress to enhance the photon sources at three of the six long straight sections. For the estimation of Touschek beam lifetime, the TRACY code is used to calculate the momentum acceptance of the linear coupled TPS 3DMBy lattice. The weak linear coupling was generated by adding some random skew quadrupoles at all quadrupole locations in order to create 1% coupling. Using the Teng’s symplectic rotation form in program may cause trouble in decoupling the oneturn coupled matrix. This report describes how we solve this decoupling problem and some useful references and comments are also presented.



WEPC034 
Highlevel Application Programs for the TPS Commissioning and Operation at NSRRC 
2079 

 F.H. Tseng, H.P. Chang, C.C. Chiang
NSRRC, Hsinchu, Taiwan



For the Taiwan Photon Source (TPS) commissioning and operation we have developed more MATLABbased application programs and tested them on the Taiwan Light Source (TLS). These additional applications built with the MATLAB Middle Layer (MML) include beta function measurement, dispersion function measurement, chromaticity measurement, chromaticity correction, and tune control. In this paper, we will illustrate what algorithms we use in these applications and show the test results. Especially, in order to get the first beam in the TPS commissioning, we adopt the RESOLVE algorithm for the beam steering and it has been built successfully in UNIXlike systems such as Mac OSX and different Linux versions. It can provide us some exercises of error finding and correction before the TPS commissioning in 2013.



WEPC035 
Double MiniBetay Lattice for TPS Storage Ring 
2082 

 M.S. Chiu, H.P. Chang, C.T. Chen, C.C. Chiang, C.C. Kuo, Y.C. Lee, H.J. Tsai, C.H. Yang
NSRRC, Hsinchu, Taiwan



Based on our previous design of double minibetay optics in one 12m straight section, NSRRC plan to implement the double minibetay lattice in three 12m straight sections in TPS storage ring. Those three locations chosen for double minibetay lattice still retain the symmetry of accelerator lattice. The two symmetric minima of the vertical beta function will be created in the center of three 12m straight sections, respectively. We strived to obtain a linear lattice such that there is no significant increase in the natural emittance. Efforts were devoted to optimize the nonlinear beam dynamics with various simulation tools. Preliminary results will be reported.



THPC064 
Design Study of Low Emittance Lattice for Taiwan Light Source at 1 GeV 
3041 

 C.Y. Lee
NTHU, Hsinchu, Taiwan
 C.C. Chiang, P.J. Chou
NSRRC, Hsinchu, Taiwan
 S.Y. Lee
IUCEEM, Bloomington, Indiana, USA



We explored the possibility that the existing TLS storage ring to be operated at 1 GeV as a high brightness VUV light source after the completion of 3 GeV Taiwan Photon Source. To increase the spectral brightness, we need to reduce the beam emittance in the storage ring as much as possible. We first pursue the lowest emittance which is possible without altering the existing hardware configuration. The theoretical minimum emittance that could be achieved at 1 GeV for nonachromatic lattice is 3.8 nmrad. However, this could not be achieved without introducing harmonic sextupoles. Preliminary results of low emittance lattice without harmonic sextupoles in TLS storage ring will be presented.


