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Proposed TDR baseline LLRF design J. Carwardine, 22 May 2012.

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Presentation on theme: "Proposed TDR baseline LLRF design J. Carwardine, 22 May 2012."— Presentation transcript:

1 Proposed TDR baseline LLRF design J. Carwardine, 22 May 2012

2 Carwardine: 9mA meeting, 22 May 2012 LLRF system layout per the RDR

3 LLRF for TDR: KCS vs DKS DKS –Essentially the RDR layout revised for Low Power config –RDR: RF Unit had one klystron feeding 3 CMs (26 cavities) –TDR: still uses groups of 3 CMs, but for Low Power config, each klystron feeds 1½ groups of 3 CMs (39 cavities) –Vector Sum control of 39 cavities, remote adjustment of Pk, QL, and phase for each cavity, mechanical tuners, piezo tuners, KCS –Each group of 3 CMs is fed from a coaxial tap-off from a single 300MW rf feed –Low Power config removes klystrons from each cluster but doesn’t change the Local PDS –Length of KCS section in ML: 26 groups of 3 CMs = 1.25km –Vector Sum control of 26 groups of 3 CMs (676 cavities) –Long loop delays due to transit times Carwardine: 9mA meeting, 22 May 2012

4 A. Yamomoto Carwardine: 9mA meeting, 22 May 2012

5 TDR Local Power Distribution System for ‘Low Power’ configuration (Showing half of an RF-Unit for KCS) Motorized variable hybrids Motorized phase shifters (one per cavity) Motorized double U-bend power tap-offs RF in 5MW load KCS (RF source: one CTO per 3 cryomodules) (Still uses 3 CM group as in RDR) ½ RF-unit for KCS (shown above) comprises: Cryomodules: 1 + ½ = 1 ½ Cavities: 5+4 + 4 = 13 Motorized double U-bends (2 per CM): 3 Motorized variable hybrids: 4+3 + 3 = 10 Motorized phase shifters: 5+4 + 4 = 13 Motorized input couplers: 5+4 + 4 = 13 Total knobs for each ½ RF Unit for KCS = 39 DKS (RF source: 2 klystrons per 3 groups of 3 cryomodules) (RDR configuration but with every third klystrons removed) ½ RF-unit for DKS comprises: Cryomodules: 1+ ½ + ½ + 1 + 1 + ½ = 4 ½ Cavities: 5+4 + 4 + 4 + 4+5 + 5+4 + 4 = 39 Motorized double U-bends (2 per CM): 9 Motorized variable hybrids: 4+3 + 3+3 + 3+4 + 4+3 + 3 = 30 Motorized phase shifters: 5+4 + 4+4 + 4+5 + 5+4 + 4 = 39 Motorized input couplers: 5+4 + 4+4 + 4+5 + 5+4 + 4 = 39 Total knobs for each ½ RF Unit for DKS = 117 S. Fukuda / C. Nantista Carwardine: 9mA meeting, 22 May 2012

6 New TDR Baseline Local Power Distribution System Variable hybrids Variable phase shifters Variable double U-bend power tap-offs RF power S. Fukuda / C. Nantista Carwardine: 9mA meeting, 22 May 2012

7 KCS – global view Carwardine: 9mA meeting, 22 May 2012 Cluster LLRF controller

8 Carwardine: 9mA meeting, 22 May 2012 Difference between KCS and DKS is the power delivery method Local processing equipment KCS LLRF concept – local at RF unit (local equipment, functionality is identical to RDR-like

9 Technical Design Report outline Part II: The ILC Baseline Reference Page counts Author 1 Introduction and overview5 2 General parameters and layout15 3 SCRF Linac Technology39 Main linac top-level parameters and general layout 2Adolphsen Cavity performance and production specifications 10Yamamoto Cavity integration (couplers, tuners etc.) 10Hayano Cryomodule design including quadrupole and cryogenic systems 10Perini RF power source 3Fukuda Low-level RF control concept 2Carwardine/Michizono Cavity and cryomodule testing 2Hayano 4 Main linac layout for a flat topography7 Layout 2Adolphsen Klystron cluster scheme RF power distribution system 4Nantista? LLRF control for Klystron Cluster Scheme 1Carwardine/Michizono 5 Main linac layout for a mountain topography7 Layout 2Adolphsen? Distributed Klystron scheme power distribution system 4Fukuda LLRF control for Distributed Klystron Scheme (‘RDR-like’) 1Carwardine/Michizono Carwardine: 9mA meeting, 22 May 2012

10 Scope of LLRF sections In Main Linac Technology (2 pages) –LLRF system hardware functional description (1 page + diagram) –LLRF system applications / functionality (1 page + diagram) In ML for flat topography (1 page) –LLRF system layout diagram –Achieved LLRF performance In ML for mountain topography (1 page) –LLRF system layout diagram –LLRF performance limitations due to large VS and long transport delays –Global control at cluster level vs fast local processing at the CM Only 4 pages allocated in total, so will need to be able to cite other papers, documents, etc for details –What do we have that can be referenced? Carwardine: 9mA meeting, 22 May 2012

11 List of functions / applications (from Julien Branlard) Global (klystron-level applications) –MIMO: second order dynamical regulator –LFF: modifies FF to minimize repetitive controller error –BLC: modifies FF to compensate beam loading –BBF: modifies setpoints to minimize beam energy error Local (cryomodule-level applications) –Gradient limiter: truncate RF/acts on SP to lower cav. Grad. –Quench detect: RF off at next pulse –Auto Loaded-Q: set and monitor cav. QL –Auto Pk/Ql control to flatten gradients –Auto piezo setup: Lorentz force detuning compensation –Energy optimizer: distribute energy losses to other stations Operations: startup, shutdown, exception management,… Carwardine: 9mA meeting, 22 May 2012

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