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Optimizing Cost and Minimizing Energy Loss for Race-Track LHeC Design Jake Skrabacz University of Notre Dame Univ. of Michigan CERN REU 2008 CERN AB-department.

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Presentation on theme: "Optimizing Cost and Minimizing Energy Loss for Race-Track LHeC Design Jake Skrabacz University of Notre Dame Univ. of Michigan CERN REU 2008 CERN AB-department."— Presentation transcript:

1 Optimizing Cost and Minimizing Energy Loss for Race-Track LHeC Design Jake Skrabacz University of Notre Dame Univ. of Michigan CERN REU 2008 CERN AB-department

2 My Problem: Conceptually LHeC: linear electron collider Basic Design: linac will be connected to a recirculation track (why?) Goal: to determine a design for the linac + recirculation structure that will… --Optimize $$$ --Minimize radiative energy loss

3 Primary Considerations in Finding Optimal Design Cost Structure (number of accelerations per revolution) Shape Size Number of revolutions Radiative energy loss

4 Secondary Considerations Transverse emittance growth from radiation Number of dipoles needed to keep upper bound on emittance growth Average length of dipoles Maximum bending dipole field needed to recirculate beam

5 Primary Shape Studied: The “Race Track” Design 4 Parameters: 1. L: length of linac and/or drift segments, [km] 2. R: radius of bends, [m] 3. bool: boolean (0 for singly-accelerating structure, 1 for doubly-accelerating) 4. N: number of revolutions

6 My Shape Proposal (Rejected): The “Ball Field” Design 5 Parameters: 1.L L : length of linac, [km] 2.L D : length of drift segments, [km] 3.R: small radius, [m] 4. α: angular spread of small circle, [rad] 5. N: number of revolutions

7 My Problem: Analytically Energy Loss to Synchrotron Radiation (around bends): Energy Gain in Linac:

8 My Problem: Computationally (my algorithm) This optimization problem calls for 8 variables: 1. Injection energy 2. Target energy 3. Energy gradient (energy gain per meter in Linac) 4. No. of revolutions 5. bool: singly acc. structure corresponds to 0, while doubly acc. corresponds to 1 6. Cost of linac per meter 7. Cost of drift section per meter 8. Cost of bending track per meter

9 Algorithm (cont.) The whole goal is to reduce the cost function to 2 variables—radius and length—then minimize it Total Cost (R,L) = 2π R N $bend + (1+δ 1, bool ) L $linac + δ 0, bool L $drift Looking at our structure, and using the energy formulas from the previous slides, you can construct a function that gives the final energy value of the e- beam, E = E (Ei, R, L, dE/dx, revs, bool) We now have the necessary restriction to our optimization problem: the final energy for the dimensions (R and L) must equal the target energy.

10 The Parameters Used 1. Injection energy = 500MeV 2. Target energy = {20, 40, 60, 80, 100, 120} GeV 3. Energy gradient = 15 MeV/m 4. No. of revolutions: trials from 1 to 8 5. bool: trials with both 0, 1 6. Cost of linac per meter = $160k/m 7. Cost of drift section per meter = $15k/m 8. Cost of bending track per meter = $50k/m

11 But how do we minimize energy loss? Create “effective cost,” which incorporates a weight parameter that gives a cost per unit energy loss Effective Cost = Total Cost + λ ×|ΔE rad | Minimize this!! Now you have the dual effect: optimize cost and, to the variable extent of the weight parameter, minimize energy loss

12 Conclusions Reject “ball field” design: reduces energy loss, but cost and size much too large relative to race track!! Across every target energy and λ value studied, found singly-accelerating structure to be optimal for both total cost and total effective cost Other optimal parameters (radius, length, number of revolution) depend on target energy and λ value chosen

13 Optimal Cost Results (optimal number of revolutions) λ / E t 20406080100120 0864333 1854332 10743322 100422211 1000211111 10000111111 Optimal Effective Cost Results λ / E t 20406080100120 0864333 1754332 10532221 100321111 1000111111 10000111111

14 Sample Result E = 80 GeV, λ = $10 million/GeV

15 Limitations Assumes a constant energy gradient Assumes cost of bending track independent of size of bend. In reality, the cost of a bending magnet increases with the dipole strength, k ∝ 1/R. Model does not yet consider lattice structure and the machine’s optics. It gives a “first look” at optimal structure by analyzing macroscopic effects (cost, energy loss, etc). Model does not yet consider operating cost.

16 Acknowledgements Univ. of Michigan: Dr. Homer Neal, Dr. Jean Krisch, Dr. Myron Campbell, Dr. Steven Goldfarb Mentor: Dr. Frank Zimmermann NSF CERN

17 Questions?

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