Requirement Details
Electron Ion Collider
F-ESR.1
Requirement details, history, relationships and interfaces associated with requirement F-ESR.1
CURRENT RECORD
ARCHIVE RECORDS
RELATIONSHIPS
INTERFACES
Record Date: 01/27/2025 16:43 | |||
Identifier: | F-ESR.1 | WBS: | 6.04 |
Date Modified: | TBD: | FALSE | |
Status Date: | Status: | Approved | |
Description: | The ESR lattice shall provide a minimum dynamic aperture of 10 sigma w.r.t Gaussian electron beam distribution in all three dimensions, horizontal, vertical, and longitudinal. With the vertical emittance being half the horizontal design emittance. | ||
Comments: |
No archive versions
Parents | |
G-ESR.1 | The ESR shall be able to accept single bunches of spin-polarized electrons as injected from the RCS at the energies specified in the MPT. [Document#:EIC-SEG-RSI-005] |
G-ESR.3 | The ESR shall provide electron bunches having the bunch parameters specified in in MPT. [Document#:EIC-SEG-RSI-005] |
Children | |
P-ESR-MAG-D13.1 | The magnet shall have a single function. |
P-ESR-MAG-D13.2 | The magnet shall be equipped with trim coils which are capable of trimming the field within +/-3.5 (%) of the Peak main bus field. (See figure P-ESR-MSG-D13.2-1) |
P-ESR-MAG-D13.3 | To operate at a fixed bus current for 5GeV,10GeV and 18GeV the magnet shall be designed to accommodate turns. (See figure P-ESR-MSG-D13.3-1) |
P-ESR-MAG-D13.5 | The magnet shall have a Dipole field. |
P-ESR-MAG-D13.6 | The magnet field shall have a vertical field direction. |
P-ESR-MAG-D13.9 | The magnet pole gap height and width shall be H=52 (mm), W=140(mm) |
P-ESR-MAG-D13.12 | The physical magnet length shall be <2.73 (m). |
P-ESR-MAG-D13.15 | The magnet shall be able to deliver an absolute nominal integrated dipole field ranging from Bmin=0(T.m) to Bmax=0.79(T.m) (See figure P-ESR-MSG-D13.15-1) |
P-ESR-MAG-D13.18 | The magnet-to-magnet variability shall be < 0.1%. |
P-ESR-MAG-D13.19 | The field shall be measured at 4 locations (see figure P-ESR-MSG-D13-19-1) as follows Harmonic Measurements region 1; Rref1=13mm centered at (-14,0) mm, Harmonic Measurements region 2; Rref2=13mm centered at (0,0) mm, Harmonic Measurements region 3; Rref3=13mm centered at (14,0), Relative field Measurements region 4; Relative to the central field at B(0,0), sampled in an Annulus 25mm>dRvol3>31mm |
P-ESR-MAG-D13.20 | The reference field for the different design energies shall be Measurement 1; Bref1=0.07 (T) at R1 Measurement 2; Bref2=0.13 (T) at R2 Measurement 3; Bref3=0.284 (T) at R2 Measurement 4; Bref4=0.284(T) at R=0 |
P-ESR-MAG-D13.21 | The magnet bore field shall have a field homogeneity in region 4, of better than dB/B<10-3 with respect to the central field at R(0,0) and shall meet the following harmonic multipole content in regions 1, 2 and 3. (Note: The following calculated multipoles values are given for reference radius of 17mm and centered on axis at x=0, y=0. *The multipole values need to be scaled accordingly in regions 1 and 3 with appropriate off axis values.) |
P-ESR-MAG-D13.21.1 | *Region 1: b1 = 10000, Region 2: b1 = 10000, *Region 3: b1 = 10000, |
P-ESR-MAG-D13.21.2 | *Region1: -4<b2<4, Region2: -4<b2<4, *Region3: -4<b2<4 |
P-ESR-MAG-D13.21.3 | *Region 1: -0.5<b3<0.6, Region 2: -0.5<b3<0.6, *Region 3: -0.5<b3<0.6, |
P-ESR-MAG-D13.21.4 | *Region 1: -1<b4< 0.5, Region 2: -1<b4< 0.5, *Region 3: -1<b4< 0.5 |
P-ESR-MAG-D13.21.5 | *Region 1: -0.5<b5 <0.5, Region 2: -0.5<b5 <0.5, *Region 3: -0.5<b5 <0.5 |
P-ESR-MAG-D13.21.6 | *Region 1: -0.5<b6 <0.5, Region 2: -0.5<b6 <0.5, *Region 3: -0.5<b6 <0.5 |
P-ESR-MAG-D13.21.7 | *Region 1: -0.5<b7 <0.5, Region 2: -0.5<b7 <0.5, *Region 3: -0.5<b7 <0.5 |
P-ESR-MAG-D13.21.8 | *Region 1: -0.5<b8 <0.5, Region 2: -0.5<b8 <0.5, *Region 3: -0.5<b8 <0.5 |
P-ESR-MAG-D13.21.9 | *Region 1: -0.5<b9 <0.5, Region 2: -0.5<b9 <0.5, *Region 3: -0.5<b9 <0.5 |
P-ESR-MAG-D13.21.10 | *Region 1: -0.5<b10 <0.5, Region 2: -0.5<b10 <0.5, *Region 3: -0.5<b10 <0.5 |
P-ESR-MAG-D13.21.11 | *Region 1: -0.5<b11 <0.5, Region 2: -0.5<b11 <0.5, *Region 3: -0.5<b11 <0.5 |
P-ESR-MAG-D13.21.12 | *Region 1: -0.5<b12 <0.5, Region 2: -0.5<b12 <0.5, *Region 3: -0.5<b12 <0.5 |
P-ESR-MAG-D13.21.13 | *Region 1: -0.5<b13 <0.5, Region 2: -0.5<b13 <0.5, *Region 3: -0.5<b13 <0.5 |
P-ESR-MAG-D13.21.14 | *Region 1: -0.5<b14 <0.5, Region 2: -0.5<b14 <0.5, *Region 3: -0.5<b14 <0.5 |
P-ESR-MAG-D13.21.15 | *Region 1: -0.5<b15 <0.5, Region2: -0.5<b15 <0.5, *Region 3: -0.5<b15 <0.5 |
P-ESR-MAG-D13.21.16 | *Region 1: -0.5<b16 <0.5, Region2: -0.5<b16 <0.5, *Region 3: -0.5<b16 <0.5 |
P-ESR-MAG-D13.22 | The magnet shall not be designed to limit CrossTalk requirements. |
P-ESR-MAG-D13.23 | < Requirement Not Applicable > |
P-ESR-MAG-D13.24 | < Requirement Not Applicable > |
P-ESR-MAG-D13.25 | < Requirement Not Applicable > |
P-ESR-MAG-D13.26 | < Requirement Not Applicable > |
P-ESR-MAG-D13.27 | The magnet shall be designed to constrain the external fringe field. |
P-ESR-MAG-D13.28 | The magnet fringe field shall not exceed 10 Gauss at a radial distance greater than 900mm from the magnet centerline |
P-ESR-MAG-D13.29 | Magnetic field position and alignment within the magnet, 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-D13.31 | Magnet installation tolerances, 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-D13.46 | 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-D13.47 | The magnet shall be designed to operate reliably given the cumulative radiation dose it will experience over the lifetime of the EIC >20 Years. |
P-ESR-MAG-D2.1 | The magnet shall have a single function. |
P-ESR-MAG-D2.2 | The magnet shall be equipped with trim coils which are capable of trimming the field within +/- 2.8(%) of the Peak main bus field. (See figure P-ESR-MSG-D2.2-1) |
P-ESR-MAG-D2.3 | To operate at a fixed bus current for 5GeV,10GeV and 18GeV the magnet shall be designed to accommodate turns. (See figure P-ESR-MSG-D2.3-1) |
P-ESR-MAG-D2.5 | The magnet shall have a Dipole field. |
P-ESR-MAG-D2.6 | The magnet field shall have a vertical field direction. |
P-ESR-MAG-D2.9 | The magnet pole gap height and width shall be H=52 (mm), W=140(mm). |
P-ESR-MAG-D2.10 | The magnet good field aperture dAx required shall be 35.0345 mm. |
P-ESR-MAG-D2.12 | The physical magnet length shall be <1.13 (m). |
P-ESR-MAG-D2.15 | The magnet shall be able to deliver an absolute nominal integrated dipole field ranging from Bmin=0(T.m) to Bmax=0.33(T.m). (See figure P-ESR-MSG-D2.15-1) |
P-ESR-MAG-D2.18 | The magnet-to-magnet variability shall be < 0.1%. |
P-ESR-MAG-D2.19 | The field shall be measured at 4 locations (See figure P-ESR-MSG-D2.19-1) as follows Harmonic Measurements region 1; Rref1=13mm centered at (-14,0) mm, Harmonic Measurements region 2; Rref2=13mm centered at (0,0) mm, Harmonic Measurements region 3; Rref3=13mm centered at (14,0), Relative field Measurements region 4; Relative to the central field at B(0,0), sampled in an Annulus 25mm>dRvol3>31mm |
P-ESR-MAG-D2.20 | The reference field for the different measurements shall be Measurement 1; Bref1=-0.375 (T) in Region1, Region2 and Region3 Measurement 2; Bref2=0.12 (T) in Region1, Region2 and Region3 Measurement 3; Bref2=0.23 (T) in Region1, Region2 and Region3 Measurement 3; Bref3=0.23 (T) in Region4 |
P-ESR-MAG-D2.21 | The magnet bore field shall have a field homogeneity in region 4, of better than dB/B<10-3 with respect to the central field at R(0,0) and shall meet the following harmonic multipole content in regions 1, 2 and 3. (Note: The following calculated multipoles values are given for reference radius of 17mm and centered on axis at x=0, y=0. *The multipole values need to be scaled accordingly in regions 1 and 3 with appropriate off axis values.) |
P-ESR-MAG-D2.21.1 | *Region1: b1 = 10000, Region2: b1 = 10000, *Region3: b1 = 10000 |
P-ESR-MAG-D2.21.2 | *Region 1: -6<b2<6, Region 2: -6<b2<6, *Region 3: -6<b2<6 |
P-ESR-MAG-D2.21.3 | *Region1: -0.5<b3<0.6, Region2: -0.5<b3<0.6, *Region3: -0.5<b3<0.6 |
P-ESR-MAG-D2.21.4 | *Region1: -1<b4< 0.5, Region2: -1<b4< 0.5, *Region 3: -1<b4< 0.5 |
P-ESR-MAG-D2.21.5 | *Region 1: -0.5<b5 <0.5, Region 2: -0.5<b5 <0.5, *Region 3: -0.5<b5 <0.5 |
P-ESR-MAG-D2.21.6 | *Region 1: -0.5<b6 <0.5, Region 2: -0.5<b6 <0.5, *Region 3: -0.5<b6 <0.5 |
P-ESR-MAG-D2.21.7 | *Region 1: -0.5<b7 <0.5, Region 2: -0.5<b7 <0.5, *Region 3: -0.5<b7 <0.5 |
P-ESR-MAG-D2.21.8 | *Region 1: -0.5<b8 <0.5, Region 2: -0.5<b8 <0.5, *Region 3: -0.5<b8 <0.5 |
P-ESR-MAG-D2.21.9 | *Region 1: -0.5<b9 <0.5, Region 2: -0.5<b9 <0.5, *Region 3: -0.5<b9 <0.5 |
P-ESR-MAG-D2.21.10 | *Region 1: -0.5<b10 <0.5, Region 2: -0.5<b10 <0.5, *Region 3: -0.5<b10 <0.5 |
P-ESR-MAG-D2.21.11 | *Region 1: -0.5<b11 <0.5, Region 2: -0.5<b11 <0.5, *Region 3: -0.5<b11 <0.5 |
P-ESR-MAG-D2.21.12 | *Region 1: -0.5<b12 <0.5, Region 2: -0.5<b12 <0.5, *Region 3: -0.5<b12 <0.5 |
P-ESR-MAG-D2.21.13 | *Region 1: -0.5<b13 <0.5, Region 2: -0.5<b13 <0.5, *Region 3: -0.5<b13 <0.5 |
P-ESR-MAG-D2.21.14 | *Region 1: -0.5<b14 <0.5, Region 2: -0.5<b14 <0.5, *Region 3: -0.5<b14 <0.5 |
P-ESR-MAG-D2.21.15 | *Region 1: -0.5<b15 <0.5, Region 2: -0.5<b15 <0.5, *Region 3: -0.5<b15 <0.5 |
P-ESR-MAG-D2.21.16 | *Region 1: -0.5<b16 <0.5, Region 2: -0.5<b16 <0.5, *Region 3: -0.5<b16 <0.5 |
P-ESR-MAG-D2.22 | The magnet shall not be designed to limit CrossTalk requirements. |
P-ESR-MAG-D2.27 | The magnet shall be designed to constrain the external fringe field |
P-ESR-MAG-D2.28 | The magnet fringe field shall not exceed 10 Gauss at a radial distance greater than 900mm from the magnet centerline |
P-ESR-MAG-D2.29 | Magnetic field position and alignment within the magnet, 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-D2.31 | Magnet installation tolerances, 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-D2.46 | 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-D2.47 | 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-ESR-MAG-Q50.1 | The magnet shall have a single function. |
P-ESR-MAG-Q50.4 | The magnet shall require shunt resistors for beam-based alignment, 5A at 5 GeV. |
P-ESR-MAG-Q50.5 | The magnet shall have a Quadrupole field. |
P-ESR-MAG-Q50.7 | The magnet shall have a normal field rotation. |
P-ESR-MAG-Q50.8 | 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-Q60.1 | The magnet shall have a single function. |
P-ESR-MAG-Q60.4 | The magnet shall require shunt resistors for beam-based alignment, 5A at 5 GeV. |
P-ESR-MAG-Q60.5 | The magnet shall have a Quadrupole field. |
P-ESR-MAG-Q60.7 | The magnet shall have a normal field rotation. |
P-ESR-MAG-Q60.8 | 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-Q80.1 | The magnet shall have a single function. |
P-ESR-MAG-Q80.4 | The magnet shall require shunt resistors for beam-based alignment, 5A at 5 GeV. |
P-ESR-MAG-Q80.5 | The magnet shall have a Quadrupole field. |
P-ESR-MAG-Q80.7 | The magnet shall have a normal field rotation. |
P-ESR-MAG-Q80.8 | 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-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 | < Requirement Not Applicable > |
P-ESR-PS-SXT.6 | The voltage to ground of the magnet being powered shall be TBD V |
P-ESR-PS-SXT.7 | < Requirement Not Applicable > |
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 | < Requirement Not Applicable > |
P-ESR-PS-SXT.12 | < Requirement Not Applicable > |
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 | < Requirement Not Applicable > |
P-ESR-PS-SXT.27 | < Requirement Not Applicable > |
P-ESR-PS-SXT.28 | < Requirement Not Applicable > |
P-ESR-PS-SXT.29 | < Requirement Not Applicable > |
P-ESR-PS-SXT.30 | < Requirement Not Applicable > |
P-ESR-PS-SXT.31 | < Requirement Not Applicable > |
P-ESR-PS-SXT.32 | < Requirement Not Applicable > |
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-VAC.10 | The maximum beam excursion orbit shall be TBD |
P-ESR-PS-SXT.36 | The design shall have thermal switches TBD |
P-ESR-VAC.11 | The vacuum chamber shall be able to absorb synchrotron radiation and carry away 10 MW of power. |
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