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F-ESR-ARC.8

Requirement details, history, relationships and interfaces associated with requirement F-ESR-ARC.8

CURRENT RECORD

Record Date: 10/10/2024 14:48
Identifier:	F-ESR-ARC.8	WBS:	6.04
Date Modified:		TBD:	FALSE
Status Date:		Status:	In Process
Description:	The sextupole wiring scheme shall accomadate the required sextupole families needed per arc to create the 60 degree FODO cell phase advance at < 10 GeV.
Comments:

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RELATIONSHIPS

Parents
G-ESR.3	The ESR shall provide electron bunches having the bunch parameters specified in [10]Â
Children
P-ESR-MAG-SXT.1	The magnet shall have a single function.
P-ESR-MAG-SXT.2	< blank >
P-ESR-MAG-SXT.3	< blank >
P-ESR-MAG-SXT.4	< blank >
P-ESR-MAG-SXT.5	The magnet shall have a Sextupole field.
P-ESR-MAG-SXT.6	< blank >
P-ESR-MAG-SXT.7	The magnet shall have a normal field rotation.
P-ESR-MAG-SXT.8	The magnet pole tip radius shall be 67.8823 mm.
P-ESR-MAG-SXT.9	< blank >
P-ESR-MAG-SXT.10	The magnet good field aperture dAx required shall be 38.8416 mm.
P-ESR-MAG-SXT.11	The magnet good field aperture dAy required shall be 11.6825 mm.
P-ESR-MAG-SXT.12	The physical magnet length shall be <0.24 m.
P-ESR-MAG-SXT.13	The magnet model length shall be 0.24 m.
P-ESR-MAG-SXT.14	< blank >
P-ESR-MAG-SXT.15	< blank >
P-ESR-MAG-SXT.16	The magnet integrated grad field G shall be 47.285 T/m2.m.
P-ESR-MAG-SXT.17	< blank >
P-ESR-MAG-SXT.18	The magnet to magnet field variability between magnets shall be within the APS spec %.
P-ESR-MAG-SXT.19	The harmonic reference radius at the design energy of 18 GeV shall be 27 (mm) .
P-ESR-MAG-SXT.20	The Field at the reference radius at the design energy of 18 GeV shall be 405 (T/m^2) .
P-ESR-MAG-SXT.21	The magnet bore field shall require the following multipole content:
P-ESR-MAG-SXT.21.1	b1 < 1 (10^-4)
P-ESR-MAG-SXT.21.2	b2 < 1 (10^-4)
P-ESR-MAG-SXT.21.3	b3 = 10000 (10^-4)
P-ESR-MAG-SXT.21.4	-3.65 < b4 < 6.92 (10^-4)
P-ESR-MAG-SXT.21.5	-2.97 < b5 < 0.29 (10^-4)
P-ESR-MAG-SXT.21.6	-1.50 < b6 < 1.50 (10^-4)
P-ESR-MAG-SXT.21.7	-0.4 < b7 < 0.51 (10^-4)
P-ESR-MAG-SXT.21.8	-1.50 < b8 < 1.50 (10^-4)
P-ESR-MAG-SXT.21.9	-40.1 < b9 < -39.86 (10^-4)
P-ESR-MAG-SXT.21.10	-1.50 < b10 < 1.50 (10^-4)
P-ESR-MAG-SXT.21.11	-1.50 < b11 < 1.50 (10^-4)
P-ESR-MAG-SXT.21.12	-1.50 < b12 < 1.50 (10^-4)
P-ESR-MAG-SXT.21.13	-1.50 < b13 < 1.50 (10^-4)
P-ESR-MAG-SXT.21.14	-1.50 < b14 < 1.50 (10^-4)
P-ESR-MAG-SXT.21.15	-2.38 < b15 < -2.35 (10^-4)
P-ESR-MAG-SXT.21.16	-1.50 < b16 < 1.50 (10^-4)
P-ESR-MAG-SXT.22	The magnet shall not be designed to limit CrossTalk requirements.
P-ESR-MAG-SXT.23	< blank >
P-ESR-MAG-SXT.24	< blank >
P-ESR-MAG-SXT.25	< blank >
P-ESR-MAG-SXT.26	< blank >
P-ESR-MAG-SXT.27	The magnet shall be designed to specifically constrain the external fringe field TBD (Yes or No)
P-ESR-MAG-SXT.28	The magnet shall be designed to meet the following fringe field requirements within the APS spec
P-ESR-MAG-SXT.29	The magnet shall be designed to have a splitable pole to accommodate the Vacuum beam pipe installation TBD (Yes or No)
P-ESR-MAG-SXT.30	The magnet shall be designed to fit within the following envelope. TBD (Yes or No)
P-ESR-MAG-SXT.31	The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC. TBD (Yes or No)
P-ESR-MAG-SXT.32	The Bore multipole content shall have a 15th order of b15<1 (10^-4)
P-ESR-MAG-SXT.33	The Bore multipole content shall have a 16th order of b16<1 (10^-4)
P-ESR-MAG-SXT.34	The magnet shall not be designed to limit Xtalk requirements
P-ESR-MAG-SXT.35	< blank >
P-ESR-MAG-SXT.36	< blank >
P-ESR-MAG-SXT.37	< blank >
P-ESR-MAG-SXT.38	< blank >
P-ESR-MAG-SXT.39	< blank >
P-ESR-MAG-SXT.40	< blank >
P-ESR-MAG-SXT.41	< blank >
P-ESR-MAG-SXT.42	< blank >
P-ESR-MAG-SXT.43	< blank >
P-ESR-MAG-SXT.44	< blank >
P-ESR-MAG-SXT.45	< blank >
P-ESR-MAG-SXT.46	< blank >
P-ESR-MAG-SXT.47	< blank >
P-ESR-MAG-SXT.48	< blank >
P-ESR-MAG-SXT.49	< blank >
P-ESR-MAG-SXT.50	< blank >
P-ESR-MAG-SXT.51	< blank >
P-ESR-MAG-SXT.52	< blank >
P-ESR-MAG-SXT.53	< blank >
P-ESR-MAG-SXT.54	< blank >
P-ESR-MAG-SXT.55	The magnet shall not be designed to constain the external fringe field
P-ESR-MAG-SXT.56	< blank >
P-ESR-MAG-SXT_LONG.1	The magnet shall have a single function.
P-ESR-MAG-SXT_LONG.2	The magnet shall require trim coils capable of trimming the field within +/- TBD (%) of the Peak field.
P-ESR-MAG-SXT_LONG.3	The magnet shall require current taps for operation TBD ( Y or N)
P-ESR-MAG-SXT_LONG.4	The magnet shall require shunt(s) for operation TBD ( Y or N)
P-ESR-MAG-SXT_LONG.5	The magnet shall have a Sextupole field.
P-ESR-MAG-SXT_LONG.7	The magnet shall have a normal field rotation.
P-ESR-MAG-SXT_LONG.8	The magnet pole tip radius shall be 67.8823 mm.
P-ESR-MAG-SXT_LONG.10	The magnet good field aperture dAx required shall be 29.6794 mm.
P-ESR-MAG-SXT_LONG.11	The magnet good field aperture dAy required shall be 19.286 mm.
P-ESR-MAG-SXT_LONG.12	The physical magnet length shall be <0.57 m.
P-ESR-MAG-SXT_LONG.13	The magnet model length shall be 0.57 m.
P-ESR-MAG-SXT_LONG.16	The magnet integrated grad field G shall be 112.302 T/m2.m.
P-ESR-MAG-SXT_LONG.18	The magnet to magnet field variability between magnets shall be TBD (%) %.
P-ESR-MAG-SXT_LONG.19	The harmonic reference radius at the design energy of 18 GeV shall be TBD (mm) .
P-ESR-MAG-SXT_LONG.20	The Field at the reference radius at the design energy of 18 GeV shall be 197 (T/m^2) .
P-ESR-MAG-SXT_LONG.21	The magnet bore field shall require the following multipole content:
P-ESR-MAG-SXT_LONG.21.1	b1 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.2	b2 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.3	b3 = 10000 (10^-4)
P-ESR-MAG-SXT_LONG.21.4	b4 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.5	b5 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.6	b6 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.7	b7 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.8	b8 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.9	b9 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.10	b10 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.11	b11 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.12	b12 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.13	b13 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.14	b14 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.15	b15 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.21.16	b16 < 1 (10^-4)
P-ESR-MAG-SXT_LONG.22	The magnet shall not be designed to limit CrossTalk requirements.
P-ESR-MAG-SXT_LONG.27	The magnet shall be designed to specifically constrain the external fringe field TBD (Yes or No)
P-ESR-MAG-SXT_LONG.28	The magnet shall be designed to meet the following fringe field requirements TBD
P-ESR-MAG-SXT_LONG.29	The magnet shall be designed to have a splitable pole to accommodate the Vacuum beam pipe installation TBD (Yes or No)
P-ESR-MAG-SXT_LONG.30	The magnet shall be designed to fit within the following envelope. TBD (Yes or No)
P-ESR-MAG-SXT_LONG.31	The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC. TBD (Yes or No)
P-ESR-PS-SXT.1	The number of Independent functions on the magnets being powered shall be 1
P-ESR-PS-SXT.2	The maximum magnet string resistance to be powered shall be TBD ohm
P-ESR-PS-SXT.3	The maximum magnet string inductance to be powered shall be TBD H
P-ESR-PS-SXT.4	The magnets being powered shall be saturated TBD Y/N
P-ESR-PS-SXT.5	< blank >
P-ESR-PS-SXT.6	The voltage to ground of the magnet being powered shall be TBD V
P-ESR-PS-SXT.7	< blank >
P-ESR-PS-SXT.8	The minimum current the PS must operate at shall be TBD A
P-ESR-PS-SXT.9	The maximum current the PS must operate at shall be TBD A
P-ESR-PS-SXT.10	The PS current type shall be NC (DC or AC)
P-ESR-PS-SXT.11	< blank >
P-ESR-PS-SXT.12	< blank >
P-ESR-PS-SXT.13	The full power bandwidth required shall be TBD
P-ESR-PS-SXT.14	The ppm of full scale current (peak to peak) shall be TBD %
P-ESR-PS-SXT.15	The time period for specified stability shall be TBD s
P-ESR-PS-SXT.16	The short term stability shall be TBD A/s
P-ESR-PS-SXT.17	The long term stability shall be TBD A/s
P-ESR-PS-SXT.18	The current setpoint resolution (min size in bits) shall be TBD bits
P-ESR-PS-SXT.19	The synchronization required between PS's shall be TBD s
P-ESR-PS-SXT.20	The synchronization timing of synchronization shall be TBD s
P-ESR-PS-SXT.21	The max allowable current ripple (peak to peak) TBD A
P-ESR-PS-SXT.22	The max current ripple frequency range (Hz) TBD Hz
P-ESR-PS-SXT.23	WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
P-ESR-PS-SXT.24	The max voltage ripple (peak to peak) shall be TBD V
P-ESR-PS-SXT.25	An NMR shall be required to measure the field TBD A/s
P-ESR-PS-SXT.26	< blank >
P-ESR-PS-SXT.27	< blank >
P-ESR-PS-SXT.28	< blank >
P-ESR-PS-SXT.29	< blank >
P-ESR-PS-SXT.30	< blank >
P-ESR-PS-SXT.31	< blank >
P-ESR-PS-SXT.32	< blank >
P-ESR-PS-SXT.33	The current required to be shunted through the magnet shall be TBD
P-ESR-PS-SXT.34	The magnet turns ratio shall be TBD
P-ESR-PS-SXT.35	The terminal voltage shall be TBD V
P-ESR-PS-SXT.36	The design shall have thermal switches TBD
P-ESR-PS-SXT.37	The thermal switch connection numbers shall be TBD
P-ESR-PS-SXT.38	The design shall have water flow switches TBD
P-ESR-PS-SXT.39	The water flow switch connections numbers shall be TBD
P-ESR-PS-SXT.40	The design shall have access controls interlocks TBD
P-ESR-PS-SXT.41	The main terminals lug details shall be TBD
P-ESR-PS-SXT.42	The lead end indications shall be TBD
P-ESR-PS-SXT.43	The lugs details for thermal switch and water switches shall be TBD
P-ESR-PS-SXT.44	The lug details for the auxiliary windings shall be TBD
P-ESR-PS-SXT.45	The A/B terminal labeling details shall be TBD
P-ESR-PS-SXT.46	The magnet drawing with terminations details shall be TBD Draw id
P-ESR-PS-SXT.47	The magnet polarity connections shall be TBD

INTERFACES

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