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F-IR.2

Requirement details, history, relationships and interfaces associated with requirement F-IR.2

CURRENT RECORD

Record Date: 01/27/2025 16:43
Identifier:	F-IR.2	WBS:	6.06.02
Date Modified:		TBD:	FALSE
Status Date:		Status:	In Process
Description:	The IR shall guide the hadron and electron beams to collide at the IP of IR6.
Comments:

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P-ESR-MAG-Q50.01	The magnet shall have a single function.
P-ESR-MAG-Q50.04	The magnet shall require shunt resistors for beam-based alignment, 5A at 5 GeV.
P-ESR-MAG-Q50.05	The magnet shall have a Quadrupole field.
P-ESR-MAG-Q50.07	The magnet shall have a normal field rotation.
P-ESR-MAG-Q50.08	The pole tip radius of the magnet shall be 40 mm.
P-ESR-MAG-Q50.12	The physical magnet length shall be <0.5 m.
P-ESR-MAG-Q50.13	The effective magnet length shall be 0.5 m.
P-ESR-MAG-Q50.16	The magnet integrated grad field G shall be 9.4 T.
P-ESR-MAG-Q50.19	The harmonic reference radius and current at 18 GeV shall be 25 (mm) and 412 (A).
P-ESR-MAG-Q50.20	The Field at the reference radius and current at 18 GeV shall be 18.9 (T/m).
P-ESR-MAG-Q50.21	The magnet bore field shall require the following multipole content:
P-ESR-MAG-Q50.21.2	b2 = 10000 , a2 = N/A
P-ESR-MAG-Q50.21.3	b3 = HV +/- 2.2 , a3 = +/- 2
P-ESR-MAG-Q50.21.4	b4 = HV +/- 2.4 , a4 = +/- 0.7
P-ESR-MAG-Q50.21.5	b5 = HV +/- 1.0 , a5 = +/- 0.5
P-ESR-MAG-Q50.21.6	b6 = HV +/- 1.0 , a6 = +/- 0.2
P-ESR-MAG-Q50.21.7	b7 = HV +/- 1.0 , a7 = +/- 0.5
P-ESR-MAG-Q50.21.8	b8 = HV +/- 1.0 , a8 = +/- 0.5
P-ESR-MAG-Q50.21.9	b9 = HV +/- 1.0 , a9 = +/- 0.5
P-ESR-MAG-Q50.21.10	b10 = HV +/- 1.0 , a10 = +/- 0.5
P-ESR-MAG-Q50.21.11	b11 = HV +/- 1.0 , a11 = +/- 0.4
P-ESR-MAG-Q50.21.12	b12 = HV +/- 1.0 , a12 = +/- 0.3
P-ESR-MAG-Q50.21.13	b13 = HV +/- 1.0 , a13 = +/- 0.2
P-ESR-MAG-Q50.21.14	b14 = HV +/- 1.0 , a14 = +/- 0.15
P-ESR-MAG-Q50.27	The magnet shall be designed to specifically constrain the external fringe field to 10 Gauss at 40mm from the RCS beamline.
P-ESR-MAG-Q50.29	The magnetic field, center and alignment, within the magnet must be known to within a translational value of +/-50 (um) and a rotational alignment value of +/-0.5(mrad).
P-ESR-MAG-Q50.31	The magnet install center and install alignment must be within a translational value of +/-150(um) and a rotational alignment value of +/-0.5(mrad).
P-ESR-MAG-Q50.32	The magnet shall have a splitable pole to facilitate the vacuum beam pipe installation.
P-ESR-MAG-Q50.46	The magnet design and verification process shall ensure the final magnet will meet the reliability needs of the EIC over it planned operational life of >20 Years.
P-ESR-MAG-Q50.47	The magnet shall be designed to operate reliably given the cumulative radiation dose of TBD Rads it will experience over the lifetime of the EIC of >20 Years.
P-ESR-MAG-Q60.01	The magnet shall have a single function.
P-ESR-MAG-Q60.04	The magnet shall require shunt resistors for beam-based alignment, 5A at 5 GeV.
P-ESR-MAG-Q60.05	The magnet shall have a Quadrupole field.
P-ESR-MAG-Q60.07	The magnet shall have a normal field rotation.
P-ESR-MAG-Q60.08	The pole tip radius of the magnet shall be 40 mm.
P-ESR-MAG-Q60.12	The physical magnet length shall be <0.6 m.
P-ESR-MAG-Q60.13	The effective magnet length shall be 0.6 m.
P-ESR-MAG-Q60.16	The magnet integrated grad field G shall be 11.0 T.
P-ESR-MAG-Q60.19	The harmonic reference radius and current at 18 GeV shall be 25 (mm) and 412 (A).
P-ESR-MAG-Q60.20	The Field at the reference radius and current at 18 GeV shall be 18.9 (T/m).
P-ESR-MAG-Q60.21	The magnet bore field shall require the following multipole content:
P-ESR-MAG-Q60.21.2	b2 = 10000 , a2 = N/A
P-ESR-MAG-Q60.21.3	b3 = HV +/- 2.2 , a3 = +/- 2
P-ESR-MAG-Q60.21.4	b4 = HV +/- 2.4 , a4 = +/- 0.7
P-ESR-MAG-Q60.21.5	b5 = HV +/- 1.0 , a5 = +/- 0.5
P-ESR-MAG-Q60.21.6	b6 = HV +/- 1.0 , a6 = +/- 0.2
P-ESR-MAG-Q60.21.7	b7 = HV +/- 1.0 , a7 = +/- 0.5
P-ESR-MAG-Q60.21.8	b8 = HV +/- 1.0 , a8 = +/- 0.5
P-ESR-MAG-Q60.21.9	b9 = HV +/- 1.0 , a9 = +/- 0.5
P-ESR-MAG-Q60.21.10	b10 = HV +/- 1.0 , a10 = +/- 0.5
P-ESR-MAG-Q60.21.11	b11 = HV +/- 1.0 , a11 = +/- 0.4
P-ESR-MAG-Q60.21.12	b12 = HV +/- 1.0 , a12 = +/- 0.3
P-ESR-MAG-Q60.21.13	b13 = HV +/- 1.0 , a13 = +/- 0.2
P-ESR-MAG-Q60.21.14	b14 = HV +/- 1.0 , a14 = +/- 0.15
P-ESR-MAG-Q60.27	The magnet shall be designed to specifically constrain the external fringe field to 10 Gauss at 40mm from the RCS beamline.
P-ESR-MAG-Q60.29	The magnetic field, center and alignment, within the magnet must be known to within a translational value of +/-50 (um) and a rotational alignment value of +/-0.5(mrad).
P-ESR-MAG-Q60.31	The magnet install center and install alignment must be within a translational value of +/-150(um) and a rotational alignment value of +/-0.5(mrad).
P-ESR-MAG-Q60.32	The magnet shall have a splitable pole to facilitate the vacuum beam pipe installation.
P-ESR-MAG-Q60.46	The magnet design and verification process shall ensure the final magnet will meet the reliability needs of the EIC over it planned operational life of >20 Years.
P-ESR-MAG-Q60.47	The magnet shall be designed to operate reliably given the cumulative radiation dose of TBD Rads it will experience over the lifetime of the EIC of >20 Years.
P-ESR-MAG-Q80.01	The magnet shall have a single function.
P-ESR-MAG-Q80.04	The magnet shall require shunt resistors for beam-based alignment, 5A at 5 GeV.
P-ESR-MAG-Q80.05	The magnet shall have a Quadrupole field.
P-ESR-MAG-Q80.07	The magnet shall have a normal field rotation.
P-ESR-MAG-Q80.08	The pole tip radius of the magnet shall be 40 mm.
P-ESR-MAG-Q80.12	The physical magnet length shall be <0.8 m.
P-ESR-MAG-Q80.13	The effective magnet length shall be 0.8 m.
P-ESR-MAG-Q80.16	The magnet integrated grad field G shall be 15.1 T.
P-ESR-MAG-Q80.19	The harmonic reference radius and current at 18 GeV shall be 25 (mm) and 412 (A).
P-ESR-MAG-Q80.20	The Field at the reference radius and current at 18 GeV shall be 18.9 (T/m).
P-ESR-MAG-Q80.21	The magnet bore field shall require the following multipole content:
P-ESR-MAG-Q80.21.2	b2 = 10000 , a2 = N/A
P-ESR-MAG-Q80.21.3	b3 = HV +/- 2.2 , a3 = +/- 2
P-ESR-MAG-Q80.21.4	b4 = HV +/- 2.4 , a4 = +/- 0.7
P-ESR-MAG-Q80.21.5	b5 = HV +/- 1.0 , a5 = +/- 0.5
P-ESR-MAG-Q80.21.6	b6 = HV +/- 1.0 , a6 = +/- 0.2
P-ESR-MAG-Q80.21.7	b7 = HV +/- 1.0 , a7 = +/- 0.5
P-ESR-MAG-Q80.21.8	b8 = HV +/- 1.0 , a8 = +/- 0.5
P-ESR-MAG-Q80.21.9	b9 = HV +/- 1.0 , a9 = +/- 0.5
P-ESR-MAG-Q80.21.10	b10 = HV +/- 1.0 , a10 = +/- 0.5
P-ESR-MAG-Q80.21.11	b11 = HV +/- 1.0 , a11 = +/- 0.4
P-ESR-MAG-Q80.21.12	b12 = HV +/- 1.0 , a12 = +/- 0.3
P-ESR-MAG-Q80.21.13	b13 = HV +/- 1.0 , a13 = +/- 0.2
P-ESR-MAG-Q80.21.14	b14 = HV +/- 1.0 , a14 = +/- 0.15
P-ESR-MAG-Q80.27	The magnet shall be designed to specifically constrain the external fringe field to 10 Gauss at 40mm from the RCS beamline.
P-ESR-MAG-Q80.29	The magnetic field, center and alignment, within the magnet must be known to within a translational value of +/-50 (um) and a rotational alignment value of +/-0.5(mrad).
P-ESR-MAG-Q80.31	The magnet install center and install alignment must be within a translational value of +/-150(um) and a rotational alignment value of +/-0.5(mrad).
P-ESR-MAG-Q80.32	The magnet shall have a splitable pole to facilitate the vacuum beam pipe installation.
P-ESR-MAG-Q80.46	The magnet design and verification process shall ensure the final magnet will meet the reliability needs of the EIC over it planned operational life of >20 Years.
P-ESR-MAG-Q80.47	The magnet shall be designed to operate reliably given the cumulative radiation dose of TBD Rads it will experience over the lifetime of the EIC of >20 Years.
P-ESR-PS-QLS2.1	The number of Independent functions on the magnets being powered shall be 1
P-ESR-PS-QLS2.2	The maximum magnet string resistance to be powered shall be TBD ohm
P-ESR-PS-QLS2.3	The maximum magnet string inductance to be powered shall be TBD H
P-ESR-PS-QLS2.4	The magnets being powered shall be saturated TBD Y/N
P-ESR-PS-QLS2.5	< Requirement Not Applicable >
P-ESR-PS-QLS2.6	The voltage to ground of the magnet being powered shall be TBD V
P-ESR-PS-QLS2.7	The nominal current of the magnets being powered shall be TBD A
P-ESR-PS-QLS2.8	The minimum current the PS must operate at shall be TBD A
P-ESR-PS-QLS2.9	The maximum current the PS must operate at shall be TBD A
P-ESR-PS-QLS2.10	The PS current type shall be NC (DC or AC)
P-ESR-PS-QLS2.11	< Requirement Not Applicable >
P-ESR-PS-QLS2.12	< Requirement Not Applicable >
P-ESR-PS-QLS2.13	The full power bandwidth required shall be TBD
P-ESR-PS-QLS2.14	The ppm of full scale current (peak to peak) shall be TBD %
P-ESR-PS-QLS2.15	The time period for specified stability shall be TBD s
P-ESR-PS-QLS2.16	The short term stability shall be TBD A/s
P-ESR-PS-QLS2.17	The long term stability shall be TBD A/s
P-ESR-PS-QLS2.18	The current setpoint resolution (min size in bits) shall be TBD bits
P-ESR-PS-QLS2.19	The synchronization required between PS's shall be TBD s
P-ESR-PS-QLS2.20	The synchronization timing of synchronization shall be TBD s
P-ESR-PS-QLS2.21	The max allowable current ripple (peak to peak) TBD A
P-ESR-PS-QLS2.22	The max current ripple frequency range (Hz) TBD Hz
P-ESR-PS-QLS2.23	WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
P-ESR-PS-QLS2.24	The max voltage ripple (peak to peak) shall be TBD V
P-ESR-PS-QLS2.25	An NMR shall be required to measure the field TBD A/s
P-ESR-PS-QLS2.26	< Requirement Not Applicable >
P-ESR-PS-QLS2.27	< Requirement Not Applicable >
P-ESR-PS-QLS2.28	< Requirement Not Applicable >
P-ESR-PS-QLS2.29	< Requirement Not Applicable >
P-ESR-PS-QLS2.30	< Requirement Not Applicable >
P-ESR-PS-QLS2.31	< Requirement Not Applicable >
P-ESR-PS-QLS2.32	< Requirement Not Applicable >
P-ESR-PS-QLS2.33	The current required to be shunted through the magnet shall be TBD
P-ESR-PS-QLS2.34	The magnet turns ratio shall be TBD
P-ESR-PS-QLS2.35	The terminal voltage shall be TBD V
P-ESR-PS-QLS2.36	The design shall have thermal switches TBD
P-ESR-PS-QLS3.1	The number of Independent functions on the magnets being powered shall be 1
P-ESR-PS-QLS3.2	The maximum magnet string resistance to be powered shall be TBD ohm
P-ESR-PS-QLS3.3	The maximum magnet string inductance to be powered shall be TBD H
P-ESR-PS-QLS3.4	The magnets being powered shall be saturated TBD Y/N
P-ESR-PS-QLS3.5	< Requirement Not Applicable >
P-ESR-PS-QLS3.6	The voltage to ground of the magnet being powered shall be TBD V
P-ESR-PS-QLS3.7	The nominal current of the magnets being powered shall be TBD A
P-ESR-PS-QLS3.8	The minimum current the PS must operate at shall be TBD A
P-ESR-PS-QLS3.9	The maximum current the PS must operate at shall be TBD A
P-ESR-PS-QLS3.10	The PS current type shall be NC (DC or AC)
P-ESR-PS-QLS3.11	< Requirement Not Applicable >
P-ESR-PS-QLS3.12	< Requirement Not Applicable >
P-ESR-PS-QLS3.13	The full power bandwidth required shall be TBD
P-ESR-PS-QLS3.14	The ppm of full scale current (peak to peak) shall be TBD %
P-ESR-PS-QLS3.15	The time period for specified stability shall be TBD s
P-ESR-PS-QLS3.16	The short term stability shall be TBD A/s
P-ESR-PS-QLS3.17	The long term stability shall be TBD A/s
P-ESR-PS-QLS3.18	The current setpoint resolution (min size in bits) shall be TBD bits
P-ESR-PS-QLS3.19	The synchronization required between PS's shall be TBD s
P-ESR-PS-QLS3.20	The synchronization timing of synchronization shall be TBD s
P-ESR-PS-QLS3.21	The max allowable current ripple (peak to peak) TBD A
P-ESR-PS-QLS3.22	The max current ripple frequency range (Hz) TBD Hz
P-ESR-PS-QLS3.23	WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
P-ESR-PS-QLS3.24	The max voltage ripple (peak to peak) shall be TBD V
P-ESR-PS-QLS3.25	An NMR shall be required to measure the field TBD A/s
P-ESR-PS-QLS3.26	< Requirement Not Applicable >
P-ESR-PS-QLS3.27	< Requirement Not Applicable >
P-ESR-PS-QLS3.28	< Requirement Not Applicable >
P-ESR-PS-QLS3.29	< Requirement Not Applicable >
P-ESR-PS-QLS3.30	< Requirement Not Applicable >
P-ESR-PS-QLS3.31	< Requirement Not Applicable >
P-ESR-PS-QLS3.32	< Requirement Not Applicable >
P-ESR-PS-QLS3.33	The current required to be shunted through the magnet shall be TBD
P-ESR-PS-QLS3.34	The magnet turns ratio shall be TBD
P-ESR-PS-QLS3.35	The terminal voltage shall be TBD V
P-ESR-PS-QLS3.36	The design shall have thermal switches TBD
P-ESR-PS-QSS1.1	The number of Independent functions on the magnets being powered shall be 1
P-ESR-PS-QSS1.2	The maximum magnet string resistance to be powered shall be TBD ohm
P-ESR-PS-QSS1.3	The maximum magnet string inductance to be powered shall be TBD H
P-ESR-PS-QSS1.4	The magnets being powered shall be saturated TBD Y/N
P-ESR-PS-QSS1.5	< Requirement Not Applicable >
P-ESR-PS-QSS1.6	The voltage to ground of the magnet being powered shall be TBD V
P-ESR-PS-QSS1.7	The nominal current of the magnets being powered shall be TBD A
P-ESR-PS-QSS1.8	The minimum current the PS must operate at shall be TBD A
P-ESR-PS-QSS1.9	The maximum current the PS must operate at shall be TBD A
P-ESR-PS-QSS1.10	The PS current type shall be NC (DC or AC)
P-ESR-PS-QSS1.11	< Requirement Not Applicable >
P-ESR-PS-QSS1.12	< Requirement Not Applicable >
P-ESR-PS-QSS1.13	The full power bandwidth required shall be TBD
P-ESR-PS-QSS1.14	The ppm of full scale current (peak to peak) shall be TBD %
P-ESR-PS-QSS1.15	The time period for specified stability shall be TBD s
P-ESR-PS-QSS1.16	The short term stability shall be TBD A/s
P-ESR-PS-QSS1.17	The long term stability shall be TBD A/s
P-ESR-PS-QSS1.18	The current setpoint resolution (min size in bits) shall be TBD bits
P-ESR-PS-QSS1.19	The synchronization required between PS's shall be TBD s
P-ESR-PS-QSS1.20	The synchronization timing of synchronization shall be TBD s
P-ESR-PS-QSS1.21	The max allowable current ripple (peak to peak) TBD A
P-ESR-PS-QSS1.22	The max current ripple frequency range (Hz) TBD Hz
P-ESR-PS-QSS1.23	WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
P-ESR-PS-QSS1.24	The max voltage ripple (peak to peak) shall be TBD V
P-ESR-PS-QSS1.25	An NMR shall be required to measure the field TBD A/s
P-ESR-PS-QSS1.26	< Requirement Not Applicable >
P-ESR-PS-QSS1.27	< Requirement Not Applicable >
P-ESR-PS-QSS1.28	< Requirement Not Applicable >
P-ESR-PS-QSS1.29	< Requirement Not Applicable >
P-ESR-PS-QSS1.30	< Requirement Not Applicable >
P-ESR-PS-QSS1.31	< Requirement Not Applicable >
P-ESR-PS-QSS1.32	< Requirement Not Applicable >
P-ESR-PS-QSS1.33	The current required to be shunted through the magnet shall be TBD
P-ESR-PS-QSS1.34	The magnet turns ratio shall be TBD
P-ESR-PS-QSS1.35	The terminal voltage shall be TBD V
P-ESR-PS-QSS1.36	The design shall have thermal switches TBD
P-ESR-PS-QSS2.1	The number of Independent functions on the magnets being powered shall be 1
P-ESR-PS-QSS2.2	The maximum magnet string resistance to be powered shall be TBD ohm
P-ESR-PS-QSS2.3	The maximum magnet string inductance to be powered shall be TBD H
P-ESR-PS-QSS2.4	The magnets being powered shall be saturated TBD Y/N
P-ESR-PS-QSS2.5	< Requirement Not Applicable >
P-ESR-PS-QSS2.6	The voltage to ground of the magnet being powered shall be TBD V
P-ESR-PS-QSS2.7	The nominal current of the magnets being powered shall be TBD A
P-ESR-PS-QSS2.8	The minimum current the PS must operate at shall be TBD A
P-ESR-PS-QSS2.9	The maximum current the PS must operate at shall be TBD A
P-ESR-PS-QSS2.10	The PS current type shall be NC (DC or AC)
P-ESR-PS-QSS2.11	< Requirement Not Applicable >
P-ESR-PS-QSS2.12	< Requirement Not Applicable >
P-ESR-PS-QSS2.13	The full power bandwidth required shall be TBD
P-ESR-PS-QSS2.14	The ppm of full scale current (peak to peak) shall be TBD %
P-ESR-PS-QSS2.15	The time period for specified stability shall be TBD s
P-ESR-PS-QSS2.16	The short term stability shall be TBD A/s
P-ESR-PS-QSS2.17	The long term stability shall be TBD A/s
P-ESR-PS-QSS2.18	The current setpoint resolution (min size in bits) shall be TBD bits
P-ESR-PS-QSS2.19	The synchronization required between PS's shall be TBD s
P-ESR-PS-QSS2.20	The synchronization timing of synchronization shall be TBD s
P-ESR-PS-QSS2.21	The max allowable current ripple (peak to peak) TBD A
P-ESR-PS-QSS2.22	The max current ripple frequency range (Hz) TBD Hz
P-ESR-PS-QSS2.23	WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
P-ESR-PS-QSS2.24	The max voltage ripple (peak to peak) shall be TBD V
P-ESR-PS-QSS2.25	An NMR shall be required to measure the field TBD A/s
P-ESR-PS-QSS2.26	< Requirement Not Applicable >
P-ESR-PS-QSS2.27	< Requirement Not Applicable >
P-ESR-PS-QSS2.28	< Requirement Not Applicable >
P-ESR-PS-QSS2.29	< Requirement Not Applicable >
P-ESR-PS-QSS2.30	< Requirement Not Applicable >
P-ESR-PS-QSS2.31	< Requirement Not Applicable >
P-ESR-PS-QSS2.32	< Requirement Not Applicable >
P-ESR-PS-QSS2.33	The current required to be shunted through the magnet shall be TBD
P-ESR-PS-QSS2.34	The magnet turns ratio shall be TBD
P-ESR-PS-QSS2.35	The terminal voltage shall be TBD V
P-ESR-PS-QSS2.36	The design shall have thermal switches TBD
P-ESR-PS-QSS3.1	The number of Independent functions on the magnets being powered shall be 1
P-ESR-PS-QSS3.2	The maximum magnet string resistance to be powered shall be TBD ohm
P-ESR-PS-QSS3.3	The maximum magnet string inductance to be powered shall be TBD H
P-ESR-PS-QSS3.4	The magnets being powered shall be saturated TBD Y/N
P-ESR-PS-QSS3.5	< Requirement Not Applicable >
P-ESR-PS-QSS3.6	The voltage to ground of the magnet being powered shall be TBD V
P-ESR-PS-QSS3.7	The nominal current of the magnets being powered shall be TBD A
P-ESR-PS-QSS3.8	The minimum current the PS must operate at shall be TBD A
P-ESR-PS-QSS3.9	The maximum current the PS must operate at shall be TBD A
P-ESR-PS-QSS3.10	The PS current type shall be NC (DC or AC)
P-ESR-PS-QSS3.11	< Requirement Not Applicable >
P-ESR-PS-QSS3.12	< Requirement Not Applicable >
P-ESR-PS-QSS3.13	The full power bandwidth required shall be TBD
P-ESR-PS-QSS3.14	The ppm of full scale current (peak to peak) shall be TBD %
P-ESR-PS-QSS3.15	The time period for specified stability shall be TBD s
P-ESR-PS-QSS3.16	The short term stability shall be TBD A/s
P-ESR-PS-QSS3.17	The long term stability shall be TBD A/s
P-ESR-PS-QSS3.18	The current setpoint resolution (min size in bits) shall be TBD bits
P-ESR-PS-QSS3.19	The synchronization required between PS's shall be TBD s
P-ESR-PS-QSS3.20	The synchronization timing of synchronization shall be TBD s
P-ESR-PS-QSS3.21	The max allowable current ripple (peak to peak) TBD A
P-ESR-PS-QSS3.22	The max current ripple frequency range (Hz) TBD Hz
P-ESR-PS-QSS3.23	WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
P-ESR-PS-QSS3.24	The max voltage ripple (peak to peak) shall be TBD V
P-ESR-PS-QSS3.25	An NMR shall be required to measure the field TBD A/s
P-ESR-PS-QSS3.26	< Requirement Not Applicable >
P-ESR-PS-QSS3.27	< Requirement Not Applicable >
P-ESR-PS-QSS3.28	< Requirement Not Applicable >
P-ESR-PS-QSS3.29	< Requirement Not Applicable >
P-ESR-PS-QSS3.30	< Requirement Not Applicable >
P-ESR-PS-QSS3.31	< Requirement Not Applicable >
P-ESR-PS-QSS3.32	< Requirement Not Applicable >
P-ESR-PS-QSS3.33	The current required to be shunted through the magnet shall be TBD
P-ESR-PS-QSS3.34	The magnet turns ratio shall be TBD
P-ESR-PS-QSS3.35	The terminal voltage shall be TBD V
P-ESR-PS-QSS3.36	The design shall have thermal switches TBD
P-ESR-PS-QSS4.1	The number of Independent functions on the magnets being powered shall be 1
P-ESR-PS-QSS4.2	The maximum magnet string resistance to be powered shall be TBD ohm
P-ESR-PS-QSS4.3	The maximum magnet string inductance to be powered shall be TBD H
P-ESR-PS-QSS4.4	The magnets being powered shall be saturated TBD Y/N
P-ESR-PS-QSS4.5	< Requirement Not Applicable >
P-ESR-PS-QSS4.6	The voltage to ground of the magnet being powered shall be TBD V
P-ESR-PS-QSS4.7	The nominal current of the magnets being powered shall be TBD A
P-ESR-PS-QSS4.8	The minimum current the PS must operate at shall be TBD A
P-ESR-PS-QSS4.9	The maximum current the PS must operate at shall be TBD A
P-ESR-PS-QSS4.10	The PS current type shall be NC (DC or AC)
P-ESR-PS-QSS4.11	< Requirement Not Applicable >
P-ESR-PS-QSS4.12	< Requirement Not Applicable >
P-ESR-PS-QSS4.13	The full power bandwidth required shall be TBD
P-ESR-PS-QSS4.14	The ppm of full scale current (peak to peak) shall be TBD %
P-ESR-PS-QSS4.15	The time period for specified stability shall be TBD s
P-ESR-PS-QSS4.16	The short term stability shall be TBD A/s
P-ESR-PS-QSS4.17	The long term stability shall be TBD A/s
P-ESR-PS-QSS4.18	The current setpoint resolution (min size in bits) shall be TBD bits
P-ESR-PS-QSS4.19	The synchronization required between PS's shall be TBD s
P-ESR-PS-QSS4.20	The synchronization timing of synchronization shall be TBD s
P-ESR-PS-QSS4.21	The max allowable current ripple (peak to peak) TBD A
P-ESR-PS-QSS4.22	The max current ripple frequency range (Hz) TBD Hz
P-ESR-PS-QSS4.23	WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
P-ESR-PS-QSS4.24	The max voltage ripple (peak to peak) shall be TBD V
P-ESR-PS-QSS4.25	An NMR shall be required to measure the field TBD A/s
P-ESR-PS-QSS4.26	< Requirement Not Applicable >
P-ESR-PS-QSS4.27	< Requirement Not Applicable >
P-ESR-PS-QSS4.28	< Requirement Not Applicable >
P-ESR-PS-QSS4.29	< Requirement Not Applicable >
P-ESR-PS-QSS4.30	< Requirement Not Applicable >
P-ESR-PS-QSS4.31	< Requirement Not Applicable >
P-ESR-PS-QSS4.32	< Requirement Not Applicable >
P-ESR-PS-QSS4.33	The current required to be shunted through the magnet shall be TBD
P-ESR-PS-QSS4.34	The magnet turns ratio shall be TBD
P-ESR-PS-QSS4.35	The terminal voltage shall be TBD V
P-ESR-PS-QSS4.36	The design shall have thermal switches TBD
P-ESR-PS-QSS5.1	The number of Independent functions on the magnets being powered shall be 1
P-ESR-PS-QSS5.2	The maximum magnet string resistance to be powered shall be TBD ohm
P-ESR-PS-QSS5.3	The maximum magnet string inductance to be powered shall be TBD H
P-ESR-PS-QSS5.4	The magnets being powered shall be saturated TBD Y/N
P-ESR-PS-QSS5.5	< Requirement Not Applicable >
P-ESR-PS-QSS5.6	The voltage to ground of the magnet being powered shall be TBD V
P-ESR-PS-QSS5.7	The nominal current of the magnets being powered shall be TBD A
P-ESR-PS-QSS5.8	The minimum current the PS must operate at shall be TBD A
P-ESR-PS-QSS5.9	The maximum current the PS must operate at shall be TBD A
P-ESR-PS-QSS5.10	The PS current type shall be NC (DC or AC)
P-ESR-PS-QSS5.11	< Requirement Not Applicable >
P-ESR-PS-QSS5.12	< Requirement Not Applicable >
P-ESR-PS-QSS5.13	The full power bandwidth required shall be TBD
P-ESR-PS-QSS5.14	The ppm of full scale current (peak to peak) shall be TBD %
P-ESR-PS-QSS5.15	The time period for specified stability shall be TBD s
P-ESR-PS-QSS5.16	The short term stability shall be TBD A/s
P-ESR-PS-QSS5.17	The long term stability shall be TBD A/s
P-ESR-PS-QSS5.18	The current setpoint resolution (min size in bits) shall be TBD bits
P-ESR-PS-QSS5.19	The synchronization required between PS's shall be TBD s
P-ESR-PS-QSS5.20	The synchronization timing of synchronization shall be TBD s
P-ESR-PS-QSS5.21	The max allowable current ripple (peak to peak) TBD A
P-ESR-PS-QSS5.22	The max current ripple frequency range (Hz) TBD Hz
P-ESR-PS-QSS5.23	WRT the ripple frequency the following resonant frequencies shall be avoided TBD Hz
P-ESR-PS-QSS5.24	The max voltage ripple (peak to peak) shall be TBD V
P-ESR-PS-QSS5.25	An NMR shall be required to measure the field TBD A/s
P-ESR-PS-QSS5.26	< Requirement Not Applicable >
P-ESR-PS-QSS5.27	< Requirement Not Applicable >
P-ESR-PS-QSS5.28	< Requirement Not Applicable >
P-ESR-PS-QSS5.29	< Requirement Not Applicable >
P-ESR-PS-QSS5.30	< Requirement Not Applicable >
P-ESR-PS-QSS5.31	< Requirement Not Applicable >
P-ESR-PS-QSS5.32	< Requirement Not Applicable >
P-ESR-PS-QSS5.33	The current required to be shunted through the magnet shall be TBD
P-ESR-PS-QSS5.35	The terminal voltage shall be TBD V
P-ESR-PS-QSS5.34	The magnet turns ratio shall be TBD
P-ESR-PS-QSS5.36	The design shall have thermal switches TBD
P-HSR-MAG-D5I.03	The magnet is a Dipole(D5I) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
P-HSR-MAG-D5I.04	The magnet is a Dipole(D5I) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
P-HSR-MAG-D5I.05	The magnet is a Dipole(D5I) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
P-HSR-MAG-D5I.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-D5I.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-D5I.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-D5I.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-D5I.10	The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
P-HSR-MAG-D5O.03	The magnet is a Dipole(D5O) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
P-HSR-MAG-D5O.04	The magnet is a Dipole(D5O) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
P-HSR-MAG-D5O.05	The magnet is a Dipole(D5O) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
P-HSR-MAG-D5O.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-D5O.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-D5O.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-D5O.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-D5O.10	The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
P-HSR-MAG-D6.03	The magnet is a Dipole(D6) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
P-HSR-MAG-D6.04	The magnet is a Dipole(D6) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
P-HSR-MAG-D6.05	The magnet is a Dipole(D6) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
P-HSR-MAG-D6.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-D6.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-D6.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-D6.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-D6.10	The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
P-HSR-MAG-D8.03	The magnet is a Dipole(D8) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
P-HSR-MAG-D8.04	The magnet is a Dipole(D8) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
P-HSR-MAG-D8.05	The magnet is a Dipole(D8) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
P-HSR-MAG-D8.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-D8.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-D8.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-D8.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-D8.10	The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
P-HSR-MAG-D9.03	The magnet is a Dipole(D9) RHIC Magnet, the multipole homogeneity measurements and transfer function are maintained in the BNL magnet repository.
P-HSR-MAG-D9.04	The magnet is a Dipole(D9) RHIC Magnet, the cross talk calculations are maintained in the BNL magnet repository.
P-HSR-MAG-D9.05	The magnet is a Dipole(D9) RHIC Magnet, the fringe field calculations are maintained in the BNL magnet repository.
P-HSR-MAG-D9.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-D9.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-D9.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-D9.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-D9.10	The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC of >20 Years.
P-HSR-MAG-Q1.03	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
P-HSR-MAG-Q1.04	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
P-HSR-MAG-Q1.05	The magnet shall not be designed to constrain the external fringe field.
P-HSR-MAG-Q1.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-Q1.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-Q1.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-Q1.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-Q1.10	The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
P-HSR-MAG-Q2.03	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
P-HSR-MAG-Q2.04	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
P-HSR-MAG-Q2.05	The magnet shall not be designed to constrain the external fringe field.
P-HSR-MAG-Q2.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-Q2.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-Q2.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-Q2.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-Q2.10	The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
P-HSR-MAG-Q3.03	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
P-HSR-MAG-Q3.04	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
P-HSR-MAG-Q3.05	The magnet shall not be designed to constrain the external fringe field.
P-HSR-MAG-Q3.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-Q3.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-Q3.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-Q3.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-Q3.10	The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
P-HSR-MAG-Q4.03	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
P-HSR-MAG-Q4.04	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
P-HSR-MAG-Q4.05	The magnet shall not be designed to constrain the external fringe field.
P-HSR-MAG-Q4.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-Q4.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-Q4.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-Q4.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-Q4.10	The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
P-HSR-MAG-Q5.03	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
P-HSR-MAG-Q5.04	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
P-HSR-MAG-Q5.05	The magnet shall not be designed to constrain the external fringe field.
P-HSR-MAG-Q5.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-Q5.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-Q5.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-Q5.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-Q5.10	The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
P-HSR-MAG-Q6.03	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
P-HSR-MAG-Q6.04	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
P-HSR-MAG-Q6.05	The magnet shall not be designed to constrain the external fringe field.
P-HSR-MAG-Q6.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-Q6.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-Q6.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-Q6.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-Q6.10	The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
P-HSR-MAG-Q7.03	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
P-HSR-MAG-Q7.04	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
P-HSR-MAG-Q7.05	The magnet shall not be designed to constrain the external fringe field.
P-HSR-MAG-Q7.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-Q7.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-Q7.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-Q7.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-Q7.10	The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
P-HSR-MAG-Q8.03	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
P-HSR-MAG-Q8.04	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
P-HSR-MAG-Q8.05	The magnet shall not be designed to constrain the external fringe field.
P-HSR-MAG-Q8.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-Q8.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-Q8.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-Q8.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-Q8.10	The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.
P-HSR-MAG-Q9.03	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its operational harmonic multipole content constraints.
P-HSR-MAG-Q9.04	The magnet shall be measured using the multipole homogeneity measurement methodology defined to satisfy its crosstalk multipole content constraints.
P-HSR-MAG-Q9.05	The magnet shall not be designed to constrain the external fringe field.
P-HSR-MAG-Q9.06	The magnet shall be designed to be cooled and sustained at its operational temperature utilizing the proposed EIC cryogenic system which meets the following constraints:
P-HSR-MAG-Q9.07	The magnet shall have an appropriate quench protection system which ensures all electromagnetic, thermal and cryogenic connected systems are not damaged in a quench event and meets the following constraints:
P-HSR-MAG-Q9.08	All electrical connection to the magnet for the main current leads, instrumentation, Voltage taps, Current taps shall meet the appropriate interface requirements specified for those connections and meet the following constraints:
P-HSR-MAG-Q9.09	The magnet is expected to sustain 20 years of EIC operation under nominal conditions. During these 20 operational years, the magnet is expected to survive the following: 40 thermal cycles, 120 quenches and 20000 power cycles.
P-HSR-MAG-Q9.10	The magnet shall be designed with components capable to withstand a radiation dose of TBD MGy, or be approved by EIC for use in a specific location as shown in the “BNL Materials” List Doc. No. TBD.

INTERFACES

This function not yet implemented.