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I checked the measured data and several TF seems to have significantly high coherence at several frequency bands as shown in the floowing.
The other TFs are not well measured due to the lockloss or have low coherence at 10-100 Hz band.

To confirm these noises really limits the current sensitivity, noise projection using these TFs are necessary.

Fig1 (BF_COILOUTF_GAS):

This measurement is estimating BF GAS coil driver (DAC) noise, so the coil driver noise of BF GAS might affect the sensitivity around 20 and 40 Hz.

Fig2 (GASMODAL_DAMP_M2):

This measurement is estimating the feedback noise of GASMODAM_DAMP_M2 filter, so this loop might affect the current sensitivity around 20 Hz.

Fig3 (MN_COILOUTF_H3):

This measurement is estimating MN H3 coil driver (DAC) noise, so the coil driver noise of MN H3 might affect the sensitivity around 30, 40, 50 Hz.

Fig4 (MN_COILOUTF_V1):

This measurement is estimating MN V1 coil driver (DAC) noise, so the coil driver noise of MN V1 might affect the sensitivity around 30-60 Hz.

Fig5 (MN_COILOUTF_V2):

This measurement is estimating MN V2 coil driver (DAC) noise, so the coil driver noise of MN V2 might affect the sensitivity around 40 and 50 Hz.

Fig6 (MN_COILOUTF_V3):

This measurement is estimating MN V3 coil driver (DAC) noise, so the coil driver noise of MN V3 might affect the sensitivity around 30-60 Hz.

Fig7 (MN_DAMP_L):

This measurement is estimating the feedback noise of MN_DAMP_L filter, so this loop might affect the current sensitivity around below 40 Hz.

Fig8 (MN_DAMP_T):

This measurement is estimating the feedback noise of MN_DAMP_T filter, so this loop might affect the current sensitivity around below 40 and around 50 Hz.

Fig9 (MN_MNOLDAMP_P):

This measurement is estimating the feedback noise of MN_MNOLDAMP_P filter, so this loop might affect the current sensitivity around below 20, 30-40, and around 50 Hz.