Requirement Details
Electron Ion Collider
F-ESR-CONT.1
Requirement details, history, relationships and interfaces associated with requirement F-ESR-CONT.1
- CURRENT RECORD
- ARCHIVE RECORDS
- RELATIONSHIPS
- INTERFACES
Record Date: 12/06/2024 11:10 | |||
Identifier: | F-ESR-CONT.1 | WBS: | 6.04 |
Date Modified: | TBD: | FALSE | |
Status Date: | Status: | In Process | |
Description: | The ESR control system shall facilitate all ESR global control requirements.  | ||
Comments: |
No archive versions
Parents | |
G-ESR.15 | The ESR shall have a control system which can operate the ESR consistent will the overall control of the other EIC system's and to ensure the ESR meets all the Physics requirements needed to deliver the physics goals of the EIC. |
Children | |
P-ESR-CONT-ALGNMNT.1 | The BBA quad strength command output rate shall be 1 Hz |
P-ESR-CONT-FEEDBACK.6 | The tune feedback measurement sample rate shall be tbd Hz |
P-ESR-CONT-FEEDBACK.7 | The tune feedback correction rate shall be tbd Hz |
P-ESR-MAG-CORR_H.1 | The magnet shall have a single function. |
P-ESR-MAG-CORR_H.2 | The magnet shall require trim coils capable of trimming the field within +/- n (%) of the Peak field. |
P-ESR-MAG-CORR_H.3 | The magnet shall not require current taps for operation. |
P-ESR-MAG-CORR_H.4 | The magnet shall not require shunt(s) for operation. |
P-ESR-MAG-CORR_H.5 | The magnet shall have a Dipole field. |
P-ESR-MAG-CORR_H.6 | The magnet field shall have a vertical field direction. |
P-ESR-MAG-CORR_H.9 | The magnet bore gap shall be 48 mm. |
P-ESR-MAG-CORR_H.10 | The magnet good field aperture dAx required shall be 38.9222 mm. |
P-ESR-MAG-CORR_H.11 | The magnet good field aperture dAy required shall be 11.4824 mm. |
P-ESR-MAG-CORR_H.12 | The physical magnet length shall be <0.2 m. |
P-ESR-MAG-CORR_H.15 | TBD |
P-ESR-MAG-CORR_H.18 | The magnet to magnet field variability between magnets shall be <5x10^-3 %. |
P-ESR-MAG-CORR_H.19 | The harmonic reference radius at the design energy of 18 GeV shall be R<TBDmm centererd at (0,0,0) . |
P-ESR-MAG-CORR_H.20 | The Field at the reference radius at the design energy of 18 GeV shall be 60e-3 (T) . |
P-ESR-MAG-CORR_H.21 | TBD |
P-ESR-MAG-CORR_H.21.1 | b1 = 10000 (10^-4) |
P-ESR-MAG-CORR_H.22 | The magnet shall not be designed to limit CrossTalk requirements. |
P-ESR-MAG-CORR_SPNQ_V.1 | The magnet shall have a single function. |
P-ESR-MAG-CORR_SPNQ_V.2 | The magnet shall require trim coils capable of trimming the field within +/- TBD (%) of the Peak field. |
P-ESR-MAG-CORR_SPNQ_V.3 | The magnet shall require current taps for operation TBD ( Y or N) |
P-ESR-MAG-CORR_SPNQ_V.4 | The magnet shall require shunt(s) for operation TBD ( Y or N) |
P-ESR-MAG-CORR_SPNQ_V.5 | The magnet shall have a Dipole field. |
P-ESR-MAG-CORR_SPNQ_V.6 | The magnet field shall have a horizontal field direction. |
P-ESR-MAG-CORR_SPNQ_V.9 | The magnet bore gap shall be 130.1 mm. |
P-ESR-MAG-CORR_SPNQ_V.10 | The magnet good field aperture dAx required shall be 38.9222 mm. |
P-ESR-MAG-CORR_SPNQ_V.11 | The magnet good field aperture dAy required shall be 22.2856 mm. |
P-ESR-MAG-CORR_SPNQ_V.12 | The physical magnet length shall be <na m. |
P-ESR-MAG-CORR_SPNQ_V.15 | TBD |
P-ESR-MAG-CORR_SPNQ_V.18 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.19 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.20 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.1 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.2 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.3 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.4 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.5 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.6 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.7 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.8 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.9 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.10 | < blank > |
P-ESR-MAG-CORR_SPNQ_V.21.11 | b11 < 100 (10^-4) |
P-ESR-MAG-CORR_SPNQ_V.21.12 | b12 < 100 (10^-4) |
P-ESR-MAG-CORR_SPNQ_V.21.13 | b13 < 100 (10^-4) |
P-ESR-MAG-CORR_SPNQ_V.21.14 | b14 < 100 (10^-4) |
P-ESR-MAG-CORR_SPNQ_V.21.15 | b15 < 100 (10^-4) |
P-ESR-MAG-CORR_SPNQ_V.21.16 | b16 < 100 (10^-4) |
P-ESR-MAG-CORR_SPNQ_V.22 | The magnet shall not be designed to limit CrossTalk requirements. |
P-ESR-MAG-CORR_SPNQ_V.27 | The magnet shall be designed to specifically constrain the external fringe field TBD (Yes or No) |
P-ESR-MAG-CORR_SPNQ_V.28 | The magnet shall be designed to meet the following fringe field requirements TBD |
P-ESR-MAG-CORR_SPNQ_V.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-CORR_SPNQ_V.30 | The magnet shall be designed to fit within the following envelope. TBD (Yes or No) |
P-ESR-MAG-CORR_SPNQ_V.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-CORR_V.1 | The magnet shall have a single function. |
P-ESR-MAG-CORR_V.2 | The magnet shall require trim coils capable of trimming the field within +/- n (%) of the Peak field. |
P-ESR-MAG-CORR_V.3 | The magnet shall not require current taps for operation. |
P-ESR-MAG-CORR_V.4 | The magnet shall not require shunt(s) for operation. |
P-ESR-MAG-CORR_V.5 | The magnet shall have a Dipole field. |
P-ESR-MAG-CORR_V.6 | The magnet field shall have a horizontal field direction. |
P-ESR-MAG-CORR_V.9 | The magnet bore gap shall be 130.1 mm. |
P-ESR-MAG-CORR_V.10 | The magnet good field aperture dAx required shall be 29.2086 mm. |
P-ESR-MAG-CORR_V.11 | The magnet good field aperture dAy required shall be 20.0738 mm. |
P-ESR-MAG-CORR_V.12 | The physical magnet length shall be <0.2 m. |
P-ESR-MAG-CORR_V.15 | TBD |
P-ESR-MAG-CORR_V.18 | The magnet to magnet field variability between magnets shall be <5x10^-3 %. |
P-ESR-MAG-CORR_V.19 | The harmonic reference radius at the design energy of 18 GeV shall be R<TBDmm centererd at (0,0,0) . |
P-ESR-MAG-CORR_V.20 | The Field at the reference radius at the design energy of 18 GeV shall be 60e-3 (T) . |
P-ESR-MAG-CORR_V.21 | TBD |
P-ESR-MAG-CORR_V.21.1 | b1 = 10000 (10^-4) |
P-ESR-MAG-CORR_V.22 | The magnet shall not be designed to limit CrossTalk requirements. |
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 with current taps at turns 2,3,4,5,11,12,13,14,15 (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 with current taps at turns 1,2,5,11,12,13. (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 ( Y or N) |
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 magnet pole tip radius shall be 40 mm. |
P-ESR-MAG-Q50.12 | The physical magnet length shall be <0.5 m. |
P-ESR-MAG-Q50.13 | The magnet model length shall be 0.5 m. |
P-ESR-MAG-Q50.16 | The magnet integrated grad field G shall be 15.774 T/m.m. |
P-ESR-MAG-Q50.19 | The harmonic reference radius at the design energy of 18 GeV shall be 25 (mm) . |
P-ESR-MAG-Q50.20 | The Field at the reference radius at the design energy of 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 (10^-4) |
P-ESR-MAG-Q50.21.3 | -4.45 < b3 < 0.01 (10^-4) |
P-ESR-MAG-Q50.21.4 | -5.3 < b4 < -0.4 (10^-4) |
P-ESR-MAG-Q50.21.5 | -0.65 < b5 < 0.18 (10^-4) |
P-ESR-MAG-Q50.21.6 | -3.57 < b6 < -2.86 (10^-4) |
P-ESR-MAG-Q50.21.7 | -1.50 < b7 < 1.50 (10^-4) |
P-ESR-MAG-Q50.21.8 | -1.50 < b8 < 1.50 (10^-4) |
P-ESR-MAG-Q50.21.9 | -1.50 < b9 < 1.50 (10^-4) |
P-ESR-MAG-Q50.21.10 | -1.93 < b10 < -1.88 (10^-4) |
P-ESR-MAG-Q50.21.11 | -1.50 < b11 < 1.50 (10^-4) |
P-ESR-MAG-Q50.21.12 | -1.50 < b12 < 1.50 (10^-4) |
P-ESR-MAG-Q50.21.13 | -1.50 < b13 < 1.50 (10^-4) |
P-ESR-MAG-Q50.21.14 | -0.18 < b14 < -0.16 (10^-4) |
P-ESR-MAG-Q50.27 | The magnet shall be designed to specifically constrain the external fringe field N (Yes or No) |
P-ESR-MAG-Q50.29 | The magnet shall be designed to have a splitable pole to accommodate the Vacuum beam pipe installation TBD (Yes or No) |
P-ESR-MAG-Q50.31 | 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-Q50.32 | The Bore multipole content shall have a 15th order of b15<1 (10^-4) |
P-ESR-MAG-Q50.46 | < blank > |
P-ESR-MAG-Q50.47 | < blank > |
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 ( Y or N) |
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 magnet pole tip radius shall be 40 mm. |
P-ESR-MAG-Q60.12 | The physical magnet length shall be <0.6 m. |
P-ESR-MAG-Q60.13 | The magnet model length shall be 0.6 m. |
P-ESR-MAG-Q60.16 | The magnet integrated grad field G shall be 6.975 T/m.m. |
P-ESR-MAG-Q60.19 | The harmonic reference radius at the design energy of 18 GeV shall be 25 (mm) . |
P-ESR-MAG-Q60.20 | The Field at the reference radius at the design energy of 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 (10^-4) |
P-ESR-MAG-Q60.21.3 | -3.71 < b3 < -0.27 (10^-4) |
P-ESR-MAG-Q60.21.4 | -4.77 < b4 < 0.01 (10^-4) |
P-ESR-MAG-Q60.21.5 | -0.69 < b5 < 0.07 (10^-4) |
P-ESR-MAG-Q60.21.6 | -3.18 < b6 < -2.56 (10^-4) |
P-ESR-MAG-Q60.21.7 | -1.50 < b7 < 1.50 (10^-4) |
P-ESR-MAG-Q60.21.8 | -1.50 < b8 < 1.50 (10^-4) |
P-ESR-MAG-Q60.21.9 | -1.50 < b9 < 1.50 (10^-4) |
P-ESR-MAG-Q60.21.10 | -1.92 < b10 < -1.52 (10^-4) |
P-ESR-MAG-Q60.21.11 | -1.50 < b11 < 1.50 (10^-4) |
P-ESR-MAG-Q60.21.12 | -1.50 < b12 < 1.50 (10^-4) |
P-ESR-MAG-Q60.21.13 | -1.50 < b13 < 1.50 (10^-4) |
P-ESR-MAG-Q60.21.14 | -0.22 < b14 < -0.18 (10^-4) |
P-ESR-MAG-Q60.27 | The magnet shall be designed to specifically constrain the external fringe field N (Yes or No) |
P-ESR-MAG-Q60.29 | The magnet shall be designed to have a splitable pole to accommodate the Vacuum beam pipe installation TBD (Yes or No) |
P-ESR-MAG-Q60.31 | 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-Q60.32 | The Bore multipole content shall have a 15th order of b15<1 (10^-4) |
P-ESR-MAG-Q60.46 | < blank > |
P-ESR-MAG-Q60.47 | < blank > |
P-ESR-MAG-Q60x2.1 | The magnet shall have a single function. |
P-ESR-MAG-Q60x2.5 | The magnet shall have a Quadrupole field. |
P-ESR-MAG-Q60x2.7 | The magnet shall have a normal field rotation. |
P-ESR-MAG-Q60x2.8 | The magnet pole tip radius shall be 67.8823 mm. |
P-ESR-MAG-Q60x2.10 | The magnet good field aperture dAx required shall be 40.4255 mm. |
P-ESR-MAG-Q60x2.11 | The magnet good field aperture dAy required shall be 20.4007 mm. |
P-ESR-MAG-Q60x2.12 | The physical magnet length shall be <1.2 m. |
P-ESR-MAG-Q60x2.13 | The magnet model length shall be 1.2 m. |
P-ESR-MAG-Q60x2.16 | The magnet integrated grad field G shall be 24.6612 T/m.m. |
P-ESR-MAG-Q60x2.18 | The magnet to magnet field variability between magnets shall be within the APS spec %. |
P-ESR-MAG-Q60x2.19 | The harmonic reference radius at the design energy of 18 GeV shall be 25 (mm) (mm,A). |
P-ESR-MAG-Q60x2.20 | The Field at the reference radius at the design energy of 18 GeV shall be 18.9 (T/m) . |
P-ESR-MAG-Q60x2.21 | The magnet bore field shall require the following multipole content: |
P-ESR-MAG-Q60x2.21.1 | b1 < 1 (10^-4) |
P-ESR-MAG-Q60x2.21.2 | b2 < 1 (10^-4) |
P-ESR-MAG-Q60x2.21.3 | b3 = 10000 (10^-4) |
P-ESR-MAG-Q60x2.21.4 | -4.15 < b4 < 5.66 (10^-4) |
P-ESR-MAG-Q60x2.21.5 | -1.97 < b5 < 0.82 (10^-4) |
P-ESR-MAG-Q60x2.21.6 | -1.50 < b6 < 1.50 (10^-4) |
P-ESR-MAG-Q60x2.21.7 | -0.12 < b7 < 0.54 (10^-4) |
P-ESR-MAG-Q60x2.21.8 | -1.50 < b8 < 1.50 (10^-4) |
P-ESR-MAG-Q60x2.21.9 | -12.67 < b9 < -12.52 (10^-4) |
P-ESR-MAG-Q60x2.21.10 | -1.50 < b10 < 1.50 (10^-4) |
P-ESR-MAG-Q60x2.21.11 | -1.50 < b11 < 1.50 (10^-4) |
P-ESR-MAG-Q60x2.21.12 | -1.50 < b12 < 1.50 (10^-4) |
P-ESR-MAG-Q60x2.21.13 | -1.50 < b13 < 1.50 (10^-4) |
P-ESR-MAG-Q60x2.21.14 | -1.50 < b14 < 1.50 (10^-4) |
P-ESR-MAG-Q60x2.21.15 | -0.47 < b15 < -0.46 (10^-4) |
P-ESR-MAG-Q60x2.21.16 | -1.50 < b16 < 1.50 (10^-4) |
P-ESR-MAG-Q60x2.22 | The magnet shall not be designed to limit CrossTalk requirements. |
P-ESR-MAG-Q60x2.23 | The magnet xtalk shall be constrained as described ; within the APS spec |
P-ESR-MAG-Q60x2.27 | The magnet shall be designed to specifically constrain the external fringe field N (Yes or No) |
P-ESR-MAG-Q60x2.29 | The magnet shall be designed to have a splitable pole to accommodate the Vacuum beam pipe installation TBD (Yes or No) |
P-ESR-MAG-Q60x2.30 | The magnet shall be designed to fit within the following envelope. TBD (Yes or No) |
P-ESR-MAG-Q60x2.31 | 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-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 ( Y or N) |
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 magnet pole tip radius shall be 40 mm. |
P-ESR-MAG-Q80.12 | The physical magnet length shall be <0.8 m. |
P-ESR-MAG-Q80.13 | The magnet model length shall be 0.8 m. |
P-ESR-MAG-Q80.16 | The magnet integrated grad field G shall be 16 T/m.m. |
P-ESR-MAG-Q80.19 | The harmonic reference radius at the design energy of 18 GeV shall be 25 (mm) . |
P-ESR-MAG-Q80.20 | The Field at the reference radius at the design energy of 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 (10^-4) |
P-ESR-MAG-Q80.21.3 | -4.45 < b3 < 0.59 (10^-4) |
P-ESR-MAG-Q80.21.4 | -3.92 < b4 < 0.5 (10^-4) |
P-ESR-MAG-Q80.21.5 | -0.55 < b5 < 0.14 (10^-4) |
P-ESR-MAG-Q80.21.6 | -3.85 < b6 < -3.01 (10^-4) |
P-ESR-MAG-Q80.21.7 | -1.50 < b7 < 1.50 (10^-4) |
P-ESR-MAG-Q80.21.8 | -1.50 < b8 < 1.50 (10^-4) |
P-ESR-MAG-Q80.21.9 | -1.50 < b9 < 1.50 (10^-4) |
P-ESR-MAG-Q80.21.10 | -1.01 < b10 < -0.98 (10^-4) |
P-ESR-MAG-Q80.21.11 | -1.50 < b11 < 1.50 (10^-4) |
P-ESR-MAG-Q80.21.12 | -1.50 < b12 < 1.50 (10^-4) |
P-ESR-MAG-Q80.21.13 | -1.50 < b12 < 1.50 (10^-4) |
P-ESR-MAG-Q80.21.14 | -0.26 < b14 < -0.2 (10^-4) |
P-ESR-MAG-Q80.27 | The magnet shall be designed to specifically constrain the external fringe field N (Yes or No) |
P-ESR-MAG-Q80.29 | The magnet shall be designed to have a splitable pole to accommodate the Vacuum beam pipe installation TBD (Yes or No) |
P-ESR-MAG-Q80.31 | 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-Q80.32 | The Bore multipole content shall have a 15th order of b15<1 (10^-4) |
P-ESR-MAG-Q80.46 | < blank > |
P-ESR-MAG-Q80.47 | < blank > |
P-ESR-MAG-Q_SKEW.1 | The magnet shall have a single function. |
P-ESR-MAG-Q_SKEW.2 | The magnet shall require trim coils capable of trimming the field within +/- TBD (%) of the Peak field. |
P-ESR-MAG-Q_SKEW.3 | The magnet shall require current taps for operation TBD ( Y or N) |
P-ESR-MAG-Q_SKEW.4 | The magnet shall require shunt(s) for operation TBD ( Y or N) |
P-ESR-MAG-Q_SKEW.5 | The magnet shall have a Quadrupole field. |
P-ESR-MAG-Q_SKEW.7 | The magnet shall have a skew field rotation. |
P-ESR-MAG-Q_SKEW.8 | The magnet pole tip radius shall be 67.8823 mm. |
P-ESR-MAG-Q_SKEW.10 | The magnet good field aperture dAx required shall be 38.1449 mm. |
P-ESR-MAG-Q_SKEW.11 | The magnet good field aperture dAy required shall be 15.2055 mm. |
P-ESR-MAG-Q_SKEW.12 | The physical magnet length shall be <0.25 m. |
P-ESR-MAG-Q_SKEW.13 | The magnet model length shall be 0.25 m. |
P-ESR-MAG-Q_SKEW.16 | The magnet integrated grad field G shall be 0 T/m.m. |
P-ESR-MAG-Q_SKEW.18 | The magnet to magnet field variability between magnets shall be TBD %. |
P-ESR-MAG-Q_SKEW.19 | The harmonic reference radius at the design energy of 18 GeV shall be TBD (mm) . |
P-ESR-MAG-Q_SKEW.20 | The field at the reference radius at the design energy of 18 GeV shall be TBD (T/m) . |
P-ESR-MAG-Q_SKEW.21 | The magnet bore field shall require the following multipole content: |
P-ESR-MAG-Q_SKEW.21.1 | b1 = b1 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.2 | b2 = 10000 (10^-4) |
P-ESR-MAG-Q_SKEW.21.3 | b3 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.4 | -1.96 < b6 < -1.26 (10^-4) |
P-ESR-MAG-Q_SKEW.21.5 | b5 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.6 | b6 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.7 | b7 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.8 | b8 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.9 | b9 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.10 | b10 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.11 | b11 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.12 | b12 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.13 | b13 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.14 | b14 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.15 | b15 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.21.16 | b16 < 1 (10^-4) |
P-ESR-MAG-Q_SKEW.22 | The magnet shall not be designed to limit CrossTalk requirements. |
P-ESR-MAG-Q_SKEW.27 | The magnet shall be designed to specifically constrain the external fringe field TBD (Yes or No) |
P-ESR-MAG-Q_SKEW.28 | The magnet shall be designed to meet the following fringe field requirements TBD |
P-ESR-MAG-Q_SKEW.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-Q_SKEW.30 | The magnet shall be designed to fit within the following envelope. TBD (Yes or No) |
P-ESR-MAG-Q_SKEW.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.1 | The magnet shall have a single function. |
P-ESR-MAG-SXT.5 | The magnet shall have a Sextupole field. |
P-ESR-MAG-SXT.7 | The magnet shall have a normal field rotation. |
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.16 | The magnet integrated grad field G shall be 47.285 T/m2.m. |
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.21.3 | 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.27 | The magnet shall be designed to specifically constrain the external fringe field TBD (Yes or No) |
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.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.46 | < blank > |
P-ESR-MAG-SXT.47 | < 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-D13.1 | The number of Independent functions on the magnets being powered shall be 1 |
P-ESR-PS-D13.2 | The magnet type being powered is DIPOLE |
P-ESR-PS-D13.3 | The magnet model being powered is D13 |
P-ESR-PS-D13.4 | Number of unique magnet strings 28 |
P-ESR-PS-D13.5 | Quantity of magnets per unique string 1, 2, 4, 5, 12, 13, 15, 16, 176 |
P-ESR-PS-D13.6 | The number of Independent functions on the magnets being powered shall be 1 |
P-ESR-PS-D13.7 | The minimum magnet resistance to be powered shall be 2.057874, 4.115748, 8.231496, 10.28937, 24.694488, 26.752362, 30.86811, 32.925984, 362.185824 mOhm |
P-ESR-PS-D13.8 | The maximum magnet resistance to be powered shall be TBD mOhm |
P-ESR-PS-D13.9 | The minimum magnet inductance to be powered shall be 0.0015625, 0.003125, 0.00625, 0.0078125, 0.01875, 0.0203125, 0.0234375, 0.025, 0.275 H |
P-ESR-PS-D13.10 | The maximum magnet inductance to be powered shall be TBD H |
P-ESR-PS-D13.11 | The max voltage to ground of the magnet being powered shall be TBD V |
P-ESR-PS-D13.12 | The minimum opperating current the PS must operate at shall be 1040, 120.85, 736.06, 992.39, 911.83, 911.83, 911.83, 911.83, 831.27 A |
P-ESR-PS-D13.13 | The maximum current the PS must operate at shall be 1040, 988.73, 977.75, 992.39, 911.83, 911.83, 911.83, 911.83, 831.27 A |
P-ESR-PS-D13.14 | The current tuning margin shall be TBD % |
P-ESR-PS-D13.15 | The current ps reliability margin shall be TBD |
P-ESR-PS-D13.16 | The PS current type shall be DC (DC or Ramped ) |
P-ESR-PS-D13.17 | The full power bandwidth required shall be N/A |
P-ESR-PS-D13.18 | The PS waveshape required shall be N/A |
P-ESR-PS-D13.19 | The peak waveshape di/dt during ramping shall be N/A A/s |
P-ESR-PS-D13.20 | The ppm of full scale current (rms) shall be *change to PPM & need to ask Physicist ppm |
P-ESR-PS-D13.21 | The time period for specified stability shall be TBD s |
P-ESR-PS-D13.22 | The short term stability shall be TBD A/s |
P-ESR-PS-D13.23 | The long term stability shall be (1 sec to 12 hrs?) TBD A/s |
P-ESR-PS-D13.24 | The current setpoint resolution (min size in bits) shall be TBD bits |
P-ESR-PS-D13.25 | The synchronization required between PS's shall be TBD s |
P-ESR-PS-D13.26 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-D13.27 | The max allowable current ripple (rms) of full scale current low (0-4kHz) and s TBD A |
P-ESR-PS-D13.28 | The max allowable current ripple (rms) of full scale current high (4kHz-1MHz) TBD A |
P-ESR-PS-D13.29 | The max current ripple frequency range (Hz) TBD Hz |
P-ESR-PS-D13.30 | WRT to the ripple frequency the following resonant frequencies shall be avoided TBD Hz |
P-ESR-PS-D13.31 | The max voltage ripple (peak to peak) shall be TBD V |
P-ESR-PS-D13.32 | An NMR in a reference magnet shall be required to measure the field TBD A/s |
P-ESR-PS-D13.33 | The current required to be shunted through the magnet shall be TBD |
P-ESR-PS-D13.34 | The magnet turns ratio shall be TBD |
P-ESR-PS-D13.35 | The terminal voltage shall be TBD V |
P-ESR-PS-D13.36 | The design shall have thermal switches TBD |
P-ESR-PS-D13.37 | The thermal switch connection numbers shall be TBD |
P-ESR-PS-D13.38 | The design shall have water flow switches TBD |
P-ESR-PS-D13.39 | The water flow switch connections numbers shall be TBD |
P-ESR-PS-D13.40 | The design shall have access controls interlocks TBD |
P-ESR-PS-D13.41 | The main terminals lug details shall be TBD |
P-ESR-PS-D13.42 | The lead end indications shall be TBD |
P-ESR-PS-D13.43 | The lugs details for thermal switch and water switches shall be TBD |
P-ESR-PS-D13.44 | The lug details for the auxiliary windings shall be TBD |
P-ESR-PS-D13.45 | The A/B terminal labeling details shall be TBD |
P-ESR-PS-D13.46 | The magnet drawing with terminations details shall be TBD Draw id |
P-ESR-PS-D13.47 | The magnet polarity connections shall be TBD |
P-ESR-PS-D2.1 | The number of Independent functions on the magnets being powered shall be 1 |
P-ESR-PS-D2.2 | The magnet type being powered is DIPOLE |
P-ESR-PS-D2.3 | The magnet model being powered is D2 |
P-ESR-PS-D2.4 | Number of unique magnet strings 7 |
P-ESR-PS-D2.5 | Quantity of magnets per unique string 1, 4, 176 |
P-ESR-PS-D2.6 | The number of Independent functions on the magnets being powered shall be 1 |
P-ESR-PS-D2.7 | The minimum magnet resistance to be powered shall be 2.4, 9.6, 422.4 mOhm |
P-ESR-PS-D2.8 | The maximum magnet resistance to be powered shall be TBD mOhm |
P-ESR-PS-D2.9 | The minimum magnet inductance to be powered shall be 0.00153, 0.00612, 0.26928 H |
P-ESR-PS-D2.10 | The maximum magnet inductance to be powered shall be TBD H |
P-ESR-PS-D2.11 | The max voltage to ground of the magnet being powered shall be TBD V |
P-ESR-PS-D2.12 | The minimum opperating current the PS must operate at shall be 409.09, 822.27, 928.64 A |
P-ESR-PS-D2.13 | The maximum current the PS must operate at shall be 863.18, 1035, 928.64 A |
P-ESR-PS-D2.14 | The current tuning margin shall be TBD % |
P-ESR-PS-D2.15 | The current ps reliability margin shall be TBD |
P-ESR-PS-D2.16 | The PS current type shall be DC (DC or Ramped ) |
P-ESR-PS-D2.17 | The full power bandwidth required shall be N/A |
P-ESR-PS-D2.18 | The PS waveshape required shall be N/A |
P-ESR-PS-D2.19 | The peak waveshape di/dt during ramping shall be N/A A/s |
P-ESR-PS-D2.20 | The ppm of full scale current (rms) shall be *change to PPM & need to ask Physicist ppm |
P-ESR-PS-D2.21 | The time period for specified stability shall be TBD s |
P-ESR-PS-D2.22 | The short term stability shall be TBD A/s |
P-ESR-PS-D2.23 | The long term stability shall be (1 sec to 12 hrs?) TBD A/s |
P-ESR-PS-D2.24 | The current setpoint resolution (min size in bits) shall be TBD bits |
P-ESR-PS-D2.25 | The synchronization required between PS's shall be TBD s |
P-ESR-PS-D2.26 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-D2.27 | The max allowable current ripple (rms) of full scale current low (0-4kHz) and s TBD A |
P-ESR-PS-D2.28 | The max allowable current ripple (rms) of full scale current high (4kHz-1MHz) TBD A |
P-ESR-PS-D2.29 | The max current ripple frequency range (Hz) TBD Hz |
P-ESR-PS-D2.30 | WRT to the ripple frequency the following resonant frequencies shall be avoided TBD Hz |
P-ESR-PS-D2.31 | The max voltage ripple (peak to peak) shall be TBD V |
P-ESR-PS-D2.32 | An NMR in a reference magnet shall be required to measure the field TBD A/s |
P-ESR-PS-D2.33 | The current required to be shunted through the magnet shall be TBD |
P-ESR-PS-D2.34 | The magnet turns ratio shall be TBD |
P-ESR-PS-D2.35 | The terminal voltage shall be TBD V |
P-ESR-PS-D2.36 | The design shall have thermal switches TBD |
P-ESR-PS-D2.37 | The thermal switch connection numbers shall be TBD |
P-ESR-PS-D2.38 | The design shall have water flow switches TBD |
P-ESR-PS-D2.39 | The water flow switch connections numbers shall be TBD |
P-ESR-PS-D2.40 | The design shall have access controls interlocks TBD |
P-ESR-PS-D2.41 | The main terminals lug details shall be TBD |
P-ESR-PS-D2.42 | The lead end indications shall be TBD |
P-ESR-PS-D2.43 | The lugs details for thermal switch and water switches shall be TBD |
P-ESR-PS-D2.44 | The lug details for the auxiliary windings shall be TBD |
P-ESR-PS-D2.45 | The A/B terminal labeling details shall be TBD |
P-ESR-PS-D2.46 | The magnet drawing with terminations details shall be TBD Draw id |
P-ESR-PS-D2.47 | The magnet polarity connections shall be TBD |
P-ESR-PS-Q50.1 | The number of Independent functions on the magnets being powered shall be 2 |
P-ESR-PS-Q50.2 | The magnet type being powered is QUADRUPOLE |
P-ESR-PS-Q50.3 | The magnet model being powered is Q50 |
P-ESR-PS-Q50.4 | Number of unique magnet strings 62 |
P-ESR-PS-Q50.5 | Quantity of magnets per unique string 1, 2, 11, 12, 15, 18, 19 |
P-ESR-PS-Q50.6 | The number of Independent functions on the magnets being powered shall be 1 |
P-ESR-PS-Q50.7 | The minimum magnet resistance to be powered shall be 30, 60, 330, 360, 450, 540, 570 mOhm |
P-ESR-PS-Q50.8 | The maximum magnet resistance to be powered shall be TBD mOhm |
P-ESR-PS-Q50.9 | The minimum magnet inductance to be powered shall be 0.017, 0.034, 0.187, 0.204, 0.255, 0.306, 0.323 H |
P-ESR-PS-Q50.10 | The maximum magnet inductance to be powered shall be TBD H |
P-ESR-PS-Q50.11 | The max voltage to ground of the magnet being powered shall be TBD V |
P-ESR-PS-Q50.12 | The minimum opperating current the PS must operate at shall be 42.14, 66, 242.4, 242.25, 243.94, 241.94, 242.08 A |
P-ESR-PS-Q50.13 | The maximum current the PS must operate at shall be 412, 317.37, 242.4, 242.25, 244.58, 243.74, 243.89 A |
P-ESR-PS-Q50.14 | The current tuning margin shall be TBD % |
P-ESR-PS-Q50.15 | The current ps reliability margin shall be TBD |
P-ESR-PS-Q50.16 | The PS current type shall be DC (DC or Ramped ) |
P-ESR-PS-Q50.17 | The full power bandwidth required shall be N/A |
P-ESR-PS-Q50.18 | The PS waveshape required shall be N/A |
P-ESR-PS-Q50.19 | The peak waveshape di/dt during ramping shall be N/A A/s |
P-ESR-PS-Q50.20 | The ppm of full scale current (rms) shall be 5 ppm |
P-ESR-PS-Q50.21 | The time period for specified stability shall be TBD s |
P-ESR-PS-Q50.22 | The short term stability shall be TBD A/s |
P-ESR-PS-Q50.23 | The long term stability shall be (1 sec to 12 hrs?) 100 A/s |
P-ESR-PS-Q50.24 | The current setpoint resolution (min size in bits) shall be TBD bits |
P-ESR-PS-Q50.25 | The synchronization required between PS's shall be TBD s |
P-ESR-PS-Q50.26 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-Q50.27 | The max allowable current ripple (rms) of full scale current low (0-4kHz) and s 5 A |
P-ESR-PS-Q50.28 | The max allowable current ripple (rms) of full scale current high (4kHz-1MHz) 5 A |
P-ESR-PS-Q50.29 | The max current ripple frequency range (Hz) TBD Hz |
P-ESR-PS-Q50.30 | WRT to the ripple frequency the following resonant frequencies shall be avoided TBD Hz |
P-ESR-PS-Q50.31 | The max voltage ripple (peak to peak) shall be TBD V |
P-ESR-PS-Q50.32 | An NMR in a reference magnet shall be required to measure the field TBD A/s |
P-ESR-PS-Q50.33 | The current required to be shunted through the magnet shall be TBD |
P-ESR-PS-Q50.34 | The magnet turns ratio shall be TBD |
P-ESR-PS-Q50.35 | The terminal voltage shall be TBD V |
P-ESR-PS-Q50.36 | The design shall have thermal switches TBD |
P-ESR-PS-Q50.37 | The thermal switch connection numbers shall be TBD |
P-ESR-PS-Q50.38 | The design shall have water flow switches TBD |
P-ESR-PS-Q50.39 | The water flow switch connections numbers shall be TBD |
P-ESR-PS-Q50.40 | The design shall have access controls interlocks TBD |
P-ESR-PS-Q50.41 | The main terminals lug details shall be TBD |
P-ESR-PS-Q50.42 | The lead end indications shall be TBD |
P-ESR-PS-Q50.43 | The lugs details for thermal switch and water switches shall be TBD |
P-ESR-PS-Q50.44 | The lug details for the auxiliary windings shall be TBD |
P-ESR-PS-Q50.45 | The A/B terminal labeling details shall be TBD |
P-ESR-PS-Q50.46 | The magnet drawing with terminations details shall be TBD Draw id |
P-ESR-PS-Q50.47 | The magnet polarity connections shall be TBD |
P-ESR-PS-Q60.1 | The number of Independent functions on the magnets being powered shall be 3 |
P-ESR-PS-Q60.2 | The magnet type being powered is QUADRUPOLE |
P-ESR-PS-Q60.3 | The magnet model being powered is Q60 |
P-ESR-PS-Q60.4 | Number of unique magnet strings 9 |
P-ESR-PS-Q60.5 | Quantity of magnets per unique string 1 |
P-ESR-PS-Q60.6 | The number of Independent functions on the magnets being powered shall be 1 |
P-ESR-PS-Q60.7 | The minimum magnet resistance to be powered shall be 35 mOhm |
P-ESR-PS-Q60.8 | The maximum magnet resistance to be powered shall be TBD mOhm |
P-ESR-PS-Q60.9 | The minimum magnet inductance to be powered shall be 0.02 H |
P-ESR-PS-Q60.10 | The maximum magnet inductance to be powered shall be TBD H |
P-ESR-PS-Q60.11 | The max voltage to ground of the magnet being powered shall be TBD V |
P-ESR-PS-Q60.12 | The minimum opperating current the PS must operate at shall be 6.13 A |
P-ESR-PS-Q60.13 | The maximum current the PS must operate at shall be 412 A |
P-ESR-PS-Q60.14 | The current tuning margin shall be TBD % |
P-ESR-PS-Q60.15 | The current ps reliability margin shall be TBD |
P-ESR-PS-Q60.16 | The PS current type shall be DC (DC or Ramped ) |
P-ESR-PS-Q60.17 | The full power bandwidth required shall be N/A |
P-ESR-PS-Q60.18 | The PS waveshape required shall be N/A |
P-ESR-PS-Q60.19 | The peak waveshape di/dt during ramping shall be N/A A/s |
P-ESR-PS-Q60.20 | The ppm of full scale current (rms) shall be 5 ppm |
P-ESR-PS-Q60.21 | The time period for specified stability shall be TBD s |
P-ESR-PS-Q60.22 | The short term stability shall be TBD A/s |
P-ESR-PS-Q60.23 | The long term stability shall be (1 sec to 12 hrs?) 100 A/s |
P-ESR-PS-Q60.24 | The current setpoint resolution (min size in bits) shall be TBD bits |
P-ESR-PS-Q60.25 | The synchronization required between PS's shall be TBD s |
P-ESR-PS-Q60.26 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-Q60.27 | The max allowable current ripple (rms) of full scale current low (0-4kHz) and s 5 A |
P-ESR-PS-Q60.28 | The max allowable current ripple (rms) of full scale current high (4kHz-1MHz) 5 A |
P-ESR-PS-Q60.29 | The max current ripple frequency range (Hz) TBD Hz |
P-ESR-PS-Q60.30 | WRT to the ripple frequency the following resonant frequencies shall be avoided TBD Hz |
P-ESR-PS-Q60.31 | The max voltage ripple (peak to peak) shall be TBD V |
P-ESR-PS-Q60.32 | An NMR in a reference magnet shall be required to measure the field TBD A/s |
P-ESR-PS-Q60.33 | The current required to be shunted through the magnet shall be TBD |
P-ESR-PS-Q60.34 | The magnet turns ratio shall be TBD |
P-ESR-PS-Q60.35 | The terminal voltage shall be TBD V |
P-ESR-PS-Q60.36 | The design shall have thermal switches TBD |
P-ESR-PS-Q60.37 | The thermal switch connection numbers shall be TBD |
P-ESR-PS-Q60.38 | The design shall have water flow switches TBD |
P-ESR-PS-Q60.39 | The water flow switch connections numbers shall be TBD |
P-ESR-PS-Q60.40 | The design shall have access controls interlocks TBD |
P-ESR-PS-Q60.41 | The main terminals lug details shall be TBD |
P-ESR-PS-Q60.42 | The lead end indications shall be TBD |
P-ESR-PS-Q60.43 | The lugs details for thermal switch and water switches shall be TBD |
P-ESR-PS-Q60.44 | The lug details for the auxiliary windings shall be TBD |
P-ESR-PS-Q60.45 | The A/B terminal labeling details shall be TBD |
P-ESR-PS-Q60.46 | The magnet drawing with terminations details shall be TBD Draw id |
P-ESR-PS-Q60.47 | The magnet polarity connections shall be TBD |
P-ESR-PS-Q80.1 | The number of Independent functions on the magnets being powered shall be 4 |
P-ESR-PS-Q80.2 | The magnet type being powered is QUADRUPOLE |
P-ESR-PS-Q80.3 | The magnet model being powered is Q80 |
P-ESR-PS-Q80.4 | Number of unique magnet strings 151 |
P-ESR-PS-Q80.5 | Quantity of magnets per unique string 1, 4, 7 |
P-ESR-PS-Q80.6 | The number of Independent functions on the magnets being powered shall be 1 |
P-ESR-PS-Q80.7 | The minimum magnet resistance to be powered shall be 44, 176, 308 mOhm |
P-ESR-PS-Q80.8 | The maximum magnet resistance to be powered shall be TBD mOhm |
P-ESR-PS-Q80.9 | The minimum magnet inductance to be powered shall be 0.027, 0.108, 0.189 H |
P-ESR-PS-Q80.10 | The maximum magnet inductance to be powered shall be TBD H |
P-ESR-PS-Q80.11 | The max voltage to ground of the magnet being powered shall be TBD V |
P-ESR-PS-Q80.12 | The minimum opperating current the PS must operate at shall be 0, 191.19, 76.08 A |
P-ESR-PS-Q80.13 | The maximum current the PS must operate at shall be 412, 192.12, 92.74 A |
P-ESR-PS-Q80.14 | The current tuning margin shall be TBD % |
P-ESR-PS-Q80.15 | The current ps reliability margin shall be TBD |
P-ESR-PS-Q80.16 | The PS current type shall be DC (DC or Ramped ) |
P-ESR-PS-Q80.17 | The full power bandwidth required shall be N/A |
P-ESR-PS-Q80.18 | The PS waveshape required shall be N/A |
P-ESR-PS-Q80.19 | The peak waveshape di/dt during ramping shall be N/A A/s |
P-ESR-PS-Q80.20 | The ppm of full scale current (rms) shall be 5 ppm |
P-ESR-PS-Q80.21 | The time period for specified stability shall be TBD s |
P-ESR-PS-Q80.22 | The short term stability shall be TBD A/s |
P-ESR-PS-Q80.23 | The long term stability shall be (1 sec to 12 hrs?) 100 A/s |
P-ESR-PS-Q80.24 | The current setpoint resolution (min size in bits) shall be TBD bits |
P-ESR-PS-Q80.25 | The synchronization required between PS's shall be TBD s |
P-ESR-PS-Q80.26 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-Q80.27 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-Q80.28 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-Q80.29 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-Q80.30 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-Q80.31 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-Q80.32 | The synchronization timing of synchronization shall be TBD s |
P-ESR-PS-Q80.33 | The current required to be shunted through the magnet shall be TBD |
P-ESR-PS-Q80.34 | The magnet turns ratio shall be TBD |
P-ESR-PS-Q80.35 | The terminal voltage shall be TBD V |
P-ESR-PS-Q80.36 | The design shall have thermal switches TBD |
P-ESR-PS-Q80.37 | The thermal switch connection numbers shall be TBD |
P-ESR-PS-Q80.38 | The design shall have water flow switches TBD |
P-ESR-PS-Q80.39 | The water flow switch connections numbers shall be TBD |
P-ESR-PS-Q80.40 | The design shall have access controls interlocks TBD |
P-ESR-PS-Q80.41 | The main terminals lug details shall be TBD |
P-ESR-PS-Q80.42 | The lead end indications shall be TBD |
P-ESR-PS-Q80.43 | The lugs details for thermal switch and water switches shall be TBD |
P-ESR-PS-Q80.44 | The lug details for the auxiliary windings shall be TBD |
P-ESR-PS-Q80.45 | The A/B terminal labeling details shall be TBD |
P-ESR-PS-Q80.46 | The magnet drawing with terminations details shall be TBD Draw id |
P-ESR-PS-Q80.47 | The magnet polarity connections shall be TBD |
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 |
P-HSR-MAG-AR_CQS(Corr-H).29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-AR_CQS(Corr-HV).29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-AR_CQS(Corr-V).29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-AR_CQS(Quad).29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-AR_CQS(Sxt).29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-AR_D6.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-AR_D8.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-AR_D9.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-BXDS01A.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-CORR_0.5m.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-CQS(Sxt).29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-D5I.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-D5O.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-D5O_D5I.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-D6.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-D8.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-D8_IR02.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-D8_IR06.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-D9.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-H5_QS3.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-IR_Q5.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-IR_Q6.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-IR_Q8.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-IR_Q9.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-IR_VKICKER_0.25.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-KA3.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q1.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q2.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q3.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q3PR.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q4.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q4PR.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q5.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q5PR.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q7.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q8.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-Q9.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-SLOWKICK_CORR.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-TQ1.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-TQ2.29 | The magnet shall be design is TBD to have a splittable pole. |
P-HSR-MAG-TQ3.29 | The magnet shall be design is TBD to have a splittable pole. |
This function not yet implemented.