1. Impedance Budget Database Olga Zagorodnova 14.04.08 BD meeting, DESY

2. Wake field calculation – estimation of the effect of the geometry variations on the bunch First codes in time domain ~ 1980 A. Novokhatski (BINP), T. Weiland (CERN) Used at DESY now: MAFIA, ABCI, CST Microwave Studio, ECHO Maxwell‘s Equations

3. http://www.desy.de/~dohlus/2004/2004.09.holgers_seminar/asym&kick_sep2004.pdf

4. wake (Green) function

5. wake potential If we know wake function then we can calculate wake potential for any bunch shape. For beam dynamics simulations we need the wake function. The numerical codes can calculate only wake potentials (usually the Gaussian bunch shape for relatively large rms width is used). But the real bunch shape is far not Gaussian one. How to obtain the wake function? Motivation

6. wake (Green) function wake potential How to obtain the wake function? The deconvolution is bad poised operation and does not help. Well developed analytical estimation for short-range wake functions of different geometries are available. Hence we can fit our numerical results to an analytical model and define free parameters of the model. Such approach is used, for example, in A. Novokhatsky, M. Timm, and T. Weiland, Single bunch energy spread in. the TESLA cryomodule, Tech. Rep. DESY-TESLA-99-16 T. Weiland, I. Zagorodnov, The Short-Range Transverse Wake Function for TESLA Accelerating Structure, DESY-TESLA-03-23 Motivation

7. There are hundreds of wakefield sources in XFEL beam line. The bunch shape changes along the beam line. Hence, a database with wake functions for all element is required. The wake functions are not functions but distributions (generalized functions). How to keep information about such functions? We need a model. Motivation

8. singular part (cannot be tabulated directly) Wake function model regular part resistive inductive capacitive it describes singularities s -  

9. Pillbox Cavity Step-out transition Tapered collimator Examples

10. Wake potential for arbitrary bunch shape derivative of the bunch shape

11. NElementfromto Effective LengthMaterialConduct. Relax. Time Oxid layer Rough ness mm 1/Omm/msecnm 1Elliptical pipe052885161Aluminium3,66E+077,10E-155300 2Pump51615266105Aluminium3,66E+087,10E-155300 3 Absorber/Round transition5266528822Copper5,80E+072,46E-145300 4Round pipe52886100652Copper5,80E+072,46E-145300 5Bellow5288531830BeCu 1742,78E+072,46E-145300 6BPM53735473100 Stainless Steel 3041,40E+062,40E-155300 7Bellow5513554330BeCu 1742,78E+072,46E-145300 8 Round/Elliptical transition6100 0 1 23 4 5678 Katrin Schuett, ZM1 Dirk Lipka, MDI Undulator intersection

12. The main structure of DB

13. The main form of data base application contains a list of element types, parameters R, L, C and links to tables w0 and w_1.

14. The click on button „General data” opens a description of the current element. This table can contain a reference to additional material: geometry description, input files for wakefield calculations, reports.

15. The same element type can appear several times along the beam line. Hence, we need to have all combinations of this element with different bunches. The click on button „Wake” opens a form to assign a bunch to the current element and to calculate the wake potential for all possible combinations

16. Plot with wake potential of the current element with selected bunch shape can be seen.

17. The next table shows a long list of unique elements and integrated wakefield parameters for each of them.

18. The click on button „Impedance Budget” opens a report with total impedance budget of the selected elements. The wakes are given for each bunch shape separately. The click on button „Total Wake“ opens a plot with the total wake of all elements with current bunch shape.