refactor: Eiger refactoring, fix test and add docs.

fix: cleanup of eiger integration
fix: Cleanup of jungfrau_joch_client
2026-02-16 14:13:55 +01:00 · 2026-02-16 14:13:55 +01:00 · 2026-02-16 14:13:55 +01:00 · 2026-02-16 14:13:55 +01:00 · 2026-02-16 14:13:55 +01:00 · 2026-02-16 14:13:55 +01:00
29 changed files with 1661 additions and 275 deletions
--- a/csaxs_bec/device_configs/bl_detectors.yaml
+++ b/csaxs_bec/device_configs/bl_detectors.yaml
@@ -9,6 +9,17 @@ eiger_1_5:
  readoutPriority: async
  softwareTrigger: False
 eiger_9:
  description: Eiger 9M detector 
  deviceClass: csaxs_bec.devices.jungfraujoch.eiger_9m.Eiger9M
  deviceConfig:
    detector_distance: 100
    beam_center: [0, 0]
  onFailure: raise
  enabled: true
  readoutPriority: async
  softwareTrigger: False
 ids_cam:
  description: IDS camera for live image acquisition
  deviceClass: csaxs_bec.devices.ids_cameras.IDSCamera
--- a/csaxs_bec/device_configs/bl_endstation.yaml
+++ b/csaxs_bec/device_configs/bl_endstation.yaml
@@ -37,6 +37,21 @@ mcs:
  readoutPriority: monitored
  softwareTrigger: false
 ##########################################################################
 ########################### FAST SHUTTER #################################
 ##########################################################################
 fsh:
  description: Fast shutter manual control and readback
  deviceClass: csaxs_bec.devices.epics.fast_shutter.cSAXSFastEpicsShutter
  deviceConfig:
    prefix: 'X12SA-ES1-TTL:'
  onFailure: raise
  enabled: true
  readoutPriority: monitored
 ##########################################################################
 ######################## SMARACT STAGES ##################################
 ##########################################################################
@@ -60,6 +75,7 @@ xbpm3x:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -22.5
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -82,6 +98,7 @@ xbpm3y:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -2
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -104,6 +121,7 @@ sl3trxi:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -5.5
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -126,6 +144,7 @@ sl3trxo:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 6
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -148,6 +167,7 @@ sl3trxb:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -5.8
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -170,6 +190,7 @@ sl3trxt:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 5.5
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -192,6 +213,7 @@ fast_shutter_n1_x:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -7
    in: 0
@@ -215,6 +237,7 @@ fast_shutter_o1_x:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -15.8
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -237,6 +260,7 @@ fast_shutter_o2_x:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -15.5
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -259,6 +283,7 @@ filter_array_1_x:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 25
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -281,6 +306,7 @@ filter_array_2_x:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 25.5
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -303,6 +329,7 @@ filter_array_3_x:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 25.8
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -325,6 +352,7 @@ filter_array_4_x:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 25
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -347,6 +375,7 @@ sl4trxi:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -5.5
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -369,6 +398,7 @@ sl4trxo:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 6
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -391,6 +421,7 @@ sl4trxb:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -5.8
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -413,6 +444,7 @@ sl4trxt:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 5.5
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -425,7 +457,7 @@ sl5trxi:
  deviceClass: csaxs_bec.devices.smaract.smaract_ophyd.SmaractMotor
  deviceConfig:
    axis_Id: C
-    host: x12sa-eb-smaract-mcs-02.psi.ch
+    host: x12sa-eb-smaract-mcs-05.psi.ch
    limits:
    - -200
    - 200
@@ -437,6 +469,7 @@ sl5trxi:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -6
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -447,7 +480,7 @@ sl5trxo:
  deviceClass: csaxs_bec.devices.smaract.smaract_ophyd.SmaractMotor
  deviceConfig:
    axis_Id: D
-    host: x12sa-eb-smaract-mcs-02.psi.ch
+    host: x12sa-eb-smaract-mcs-05.psi.ch
    limits:
    - -200
    - 200
@@ -459,6 +492,7 @@ sl5trxo:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 5.5
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -469,7 +503,7 @@ sl5trxb:
  deviceClass: csaxs_bec.devices.smaract.smaract_ophyd.SmaractMotor
  deviceConfig:
    axis_Id: E
-    host: x12sa-eb-smaract-mcs-02.psi.ch
+    host: x12sa-eb-smaract-mcs-05.psi.ch
    limits:
    - -200
    - 200
@@ -481,6 +515,7 @@ sl5trxb:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -5.5
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -491,7 +526,7 @@ sl5trxt:
  deviceClass: csaxs_bec.devices.smaract.smaract_ophyd.SmaractMotor
  deviceConfig:
    axis_Id: F
-    host: x12sa-eb-smaract-mcs-02.psi.ch
+    host: x12sa-eb-smaract-mcs-05.psi.ch
    limits:
    - -200
    - 200
@@ -503,6 +538,7 @@ sl5trxt:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 6
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -513,7 +549,7 @@ xbimtrx:
  deviceClass: csaxs_bec.devices.smaract.smaract_ophyd.SmaractMotor
  deviceConfig:
    axis_Id: A
-    host: x12sa-eb-smaract-mcs-02.psi.ch
+    host: x12sa-eb-smaract-mcs-05.psi.ch
    limits:
    - -200
    - 200
@@ -525,6 +561,7 @@ xbimtrx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: -14.7
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
@@ -535,7 +572,7 @@ xbimtry:
  deviceClass: csaxs_bec.devices.smaract.smaract_ophyd.SmaractMotor
  deviceConfig:
    axis_Id: B
-    host: x12sa-eb-smaract-mcs-02.psi.ch
+    host: x12sa-eb-smaract-mcs-05.psi.ch
    limits:
    - -200
    - 200
@@ -547,6 +584,7 @@ xbimtry:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    init_position: 0
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
--- a/csaxs_bec/device_configs/bl_optics_hutch.yaml
+++ b/csaxs_bec/device_configs/bl_optics_hutch.yaml
@@ -89,6 +89,7 @@ xbpm2x:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
    bl_smar_stage: 0
@@ -108,6 +109,7 @@ xbpm2y:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
    bl_smar_stage: 1
@@ -127,6 +129,7 @@ cu_foilx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
    bl_smar_stage: 2
@@ -146,6 +149,7 @@ scinx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    # bl_smar_stage to use csaxs reference method. assign number according to axis channel
    bl_smar_stage: 3
--- a/csaxs_bec/device_configs/ptycho_flomni.yaml
+++ b/csaxs_bec/device_configs/ptycho_flomni.yaml
@@ -17,6 +17,7 @@ feyex:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: -16.267
    out: -1
@@ -35,6 +36,7 @@ feyey:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: -10.467
 fheater:
@@ -52,6 +54,7 @@ fheater:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
 foptx:
  description: Optics X
  deviceClass: csaxs_bec.devices.omny.galil.fgalil_ophyd.FlomniGalilMotor
@@ -67,6 +70,7 @@ foptx:
  onFailure: buffer
  readOnly: true
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: -13.761
 fopty:
@@ -84,6 +88,7 @@ fopty:
  onFailure: buffer
  readOnly: true
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0.552
    out: 0.752
@@ -102,6 +107,7 @@ foptz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 23
 fsamroy:
@@ -119,6 +125,7 @@ fsamroy:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
 fsamx:
  description: Sample coarse X
  deviceClass: csaxs_bec.devices.omny.galil.fgalil_ophyd.FlomniGalilMotor
@@ -134,6 +141,7 @@ fsamx:
  onFailure: buffer
  readOnly: true
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: -1.1
 fsamy:
@@ -151,6 +159,7 @@ fsamy:
  onFailure: buffer
  readOnly: true
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 2.75
 ftracky:
@@ -168,6 +177,7 @@ ftracky:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
 ftrackz:
  description: Laser Tracker coarse Z
  deviceClass: csaxs_bec.devices.omny.galil.fgalil_ophyd.FlomniGalilMotor
@@ -183,6 +193,7 @@ ftrackz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
 ftransx:
  description: Sample transer X
  deviceClass: csaxs_bec.devices.omny.galil.fgalil_ophyd.FlomniGalilMotor
@@ -198,6 +209,7 @@ ftransx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
 ftransy:
  description: Sample transer Y
  deviceClass: csaxs_bec.devices.omny.galil.fgalil_ophyd.FlomniGalilMotor
@@ -213,6 +225,7 @@ ftransy:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    sensor_voltage: -2.4
 ftransz:
@@ -230,6 +243,7 @@ ftransz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
 ftray:
  description: Sample transfer tray
  deviceClass: csaxs_bec.devices.omny.galil.fgalil_ophyd.FlomniGalilMotor
@@ -245,6 +259,7 @@ ftray:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
 ############################################################
@@ -279,6 +294,7 @@ fosax:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 9.124
    out: 5.3
@@ -297,6 +313,7 @@ fosay:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0.367
 fosaz:
@@ -314,6 +331,7 @@ fosaz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 8.5
    out: 6
@@ -334,6 +352,7 @@ rtx:
  onFailure: buffer
  readOnly: false
  readoutPriority: on_request
  connectionTimeout: 20
  userParameter:
    low_signal: 10000
    min_signal: 9000
@@ -350,6 +369,7 @@ rty:
  onFailure: buffer
  readOnly: false
  readoutPriority: on_request
  connectionTimeout: 20
  userParameter:
    tomo_additional_offsety: 0
 rtz:
@@ -364,6 +384,7 @@ rtz:
  onFailure: buffer
  readOnly: false
  readoutPriority: on_request
  connectionTimeout: 20
 ############################################################
 ####################### Cameras ############################
@@ -408,20 +429,20 @@ cam_xeye:
  readOnly: false
  readoutPriority: async
-cam_ids_rgb:
+# cam_ids_rgb:
-  description: Camera flOMNI Xray eye ID203
+#   description: Camera flOMNI Xray eye ID203
-  deviceClass: csaxs_bec.devices.ids_cameras.ids_camera.IDSCamera
+#   deviceClass: csaxs_bec.devices.ids_cameras.ids_camera.IDSCamera
-  deviceConfig:
+#   deviceConfig:
-    camera_id: 203
+#     camera_id: 203
-    bits_per_pixel: 24
+#     bits_per_pixel: 24
-    num_rotation_90: 3
+#     num_rotation_90: 3
-    transpose: false
+#     transpose: false
-    force_monochrome: true
+#     force_monochrome: true
-    m_n_colormode: 1
+#     m_n_colormode: 1
-  enabled: true
+#   enabled: true
-  onFailure: buffer
+#   onFailure: buffer
-  readOnly: false
+#   readOnly: false
-  readoutPriority: async
+#   readoutPriority: async
 # ############################################################
@@ -439,8 +460,8 @@ flomni_temphum:
 # ########## OMNY / flOMNI / LamNI fast shutter ##############
 # ############################################################
 omnyfsh:
-  description: omnyfsh connects to read fast shutter at X12 if in that network
+  description: omnyfsh connects to  fast shutter at X12 if device fsh exists
-  deviceClass: csaxs_bec.devices.omny.shutter.OMNYFastEpicsShutter
+  deviceClass: csaxs_bec.devices.omny.shutter.OMNYFastShutter
  deviceConfig: {}
  enabled: true
  onFailure: buffer
--- a/csaxs_bec/device_configs/ptycho_lamni.yaml
+++ b/csaxs_bec/device_configs/ptycho_lamni.yaml
@@ -19,6 +19,7 @@ leyex:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 14.117
 leyey:
@@ -38,6 +39,7 @@ leyey:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 48.069
    out: 0.5
@@ -58,6 +60,7 @@ loptx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: -0.244
    out: -0.699
@@ -78,6 +81,7 @@ lopty:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 3.724
    out: 3.53
@@ -98,6 +102,7 @@ loptz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
 lsamrot:
  description: Sample rotation
  deviceClass: csaxs_bec.devices.omny.galil.lgalil_ophyd.LamniGalilMotor
@@ -115,6 +120,7 @@ lsamrot:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
 lsamx:
  description: Sample coarse X
  deviceClass: csaxs_bec.devices.omny.galil.lgalil_ophyd.LamniGalilMotor
@@ -132,6 +138,7 @@ lsamx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    center: 8.768
 lsamy:
@@ -151,6 +158,7 @@ lsamy:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    center: 10.041
@@ -176,6 +184,7 @@ losax:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: -1.442
 losay:
@@ -195,6 +204,7 @@ losay:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: -0.171
    out: 3.8
@@ -215,6 +225,7 @@ losaz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: -1
    out: -3
@@ -238,6 +249,7 @@ rtx:
  deviceTags:
  - lamni
  readoutPriority: baseline
  connectionTimeout: 20
  enabled: true
  readOnly: False
 rty:
@@ -255,6 +267,7 @@ rty:
  deviceTags:
  - lamni
  readoutPriority: baseline
  connectionTimeout: 20
  enabled: true
  readOnly: False
--- a/csaxs_bec/device_configs/ptycho_omny.yaml
+++ b/csaxs_bec/device_configs/ptycho_omny.yaml
@@ -69,6 +69,7 @@ rtx:
  onFailure: buffer
  readOnly: false
  readoutPriority: on_request
  connectionTimeout: 20
  userParameter:
    low_signal: 8500
    min_signal: 8000
@@ -84,6 +85,7 @@ rty:
  onFailure: buffer
  readOnly: false
  readoutPriority: on_request
  connectionTimeout: 20
  userParameter:
    tomo_additional_offsety: 0
 rtz:
@@ -98,6 +100,7 @@ rtz:
  onFailure: buffer
  readOnly: false
  readoutPriority: on_request
  connectionTimeout: 20
 # ############################################################
 # ##################### OMNY samples #########################
@@ -165,6 +168,7 @@ ofzpx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: -0.4317
 ofzpy:
@@ -184,6 +188,7 @@ ofzpy:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0.7944
    out: 0.6377
@@ -204,6 +209,7 @@ ofzpz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0
 otransx:
@@ -223,6 +229,7 @@ otransx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0
 otransy:
@@ -242,6 +249,7 @@ otransy:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    up_position: -1.2
    gripper_sensorvoltagetarget: -2.30
@@ -262,6 +270,7 @@ otransz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0
 osamx:
@@ -281,6 +290,7 @@ osamx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: -0.1
 osamz:
@@ -300,6 +310,7 @@ osamz:
  onFailure: buffer
  readOnly: true
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0
 oosay:
@@ -319,6 +330,7 @@ oosay:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    near_field_in: 0.531
    far_field_in: 0.4122
@@ -339,6 +351,7 @@ oosax:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    near_field_in: 3.2044
    far_field_in: 3.022
@@ -359,6 +372,7 @@ oosaz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    near_field_in: -0.4452
    far_field_in: 6.5
@@ -379,6 +393,7 @@ oparkz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0
 oshuttleopen:
@@ -398,6 +413,7 @@ oshuttleopen:
  onFailure: buffer
  readOnly: true
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0
 oshuttlealign:
@@ -417,6 +433,7 @@ oshuttlealign:
  onFailure: buffer
  readOnly: true
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0
 osamy:
@@ -436,6 +453,7 @@ osamy:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0
 otracky:
@@ -455,6 +473,7 @@ otracky:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    start_pos: -4.3431
 osamroy:
@@ -474,6 +493,7 @@ osamroy:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    in: 0
 otrackz:
@@ -493,6 +513,7 @@ otrackz:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    start_pos: -0.6948
 oeyex:
@@ -512,6 +533,7 @@ oeyex:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    xray_in: -45.7394
 oeyez:
@@ -531,6 +553,7 @@ oeyez:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    xray_in: -2
 oeyey:
@@ -550,6 +573,7 @@ oeyey:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    xray_in: 0.0229
@@ -572,6 +596,7 @@ ocsx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    nothing: 0
 ocsy:
@@ -589,6 +614,7 @@ ocsy:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    nothing: 0
 oshield:
@@ -606,5 +632,6 @@ oshield:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  userParameter:
    nothing: 0
--- a/csaxs_bec/device_configs/user_setup.yaml
+++ b/csaxs_bec/device_configs/user_setup.yaml
@@ -1 +1,15 @@
 ############################################################
 ############################################################
 ##################### EPS ##################################
 ############################################################
 x12saEPS:
  description: X12SA EPS info and control
  deviceClass: csaxs_bec.devices.epics.eps.EPS
  deviceConfig: {}
  enabled: true
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
--- a/csaxs_bec/device_configs/user_template.yaml
+++ b/csaxs_bec/device_configs/user_template.yaml
@@ -64,6 +64,7 @@ npx:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  deviceTags:
  - npoint
 npy:
@@ -81,5 +82,6 @@ npy:
  onFailure: buffer
  readOnly: false
  readoutPriority: baseline
  connectionTimeout: 20
  deviceTags:
  - npoint
--- a/csaxs_bec/devices/epics/delay_generator_csaxs/README.md
+++ b/csaxs_bec/devices/epics/delay_generator_csaxs/README.md
@@ -37,7 +37,7 @@ to interrupt and ongoing sequence if needed.
 - a = t0 + 2ms (2ms delay to allow the shutter to open)
 - b = a + 1us (short pulse)
 - c = t0
- d = a + exp_time * burst_count + 1ms (to allow the shutter to close)
+- d = a + exp_time * burst_count
 - e = d
 - f = e + 1us (short pulse to OR gate for MCS triggering)
--- a/csaxs_bec/devices/epics/delay_generator_csaxs/ddg_1.py
+++ b/csaxs_bec/devices/epics/delay_generator_csaxs/ddg_1.py
@@ -24,7 +24,7 @@ DELAY CHANNELS:
 - a = t0 + 2ms (2ms delay to allow the shutter to open)
 - b = a + 1us (short pulse)
 - c = t0
- d = a + exp_time * burst_count + 1ms (to allow the shutter to close)
+- d = a + exp_time * burst_count
 - e = d
 - f = e + 1us (short pulse to OR gate for MCS triggering)
 """
@@ -37,7 +37,9 @@ import traceback
 from typing import TYPE_CHECKING
 from bec_lib.logger import bec_logger
-from ophyd_devices import CompareStatus, DeviceStatus, TransitionStatus
+from ophyd import Component as Cpt
 from ophyd import EpicsSignalRO, Kind
 from ophyd_devices import CompareStatus, DeviceStatus, StatusBase, TransitionStatus
 from ophyd_devices.interfaces.base_classes.psi_device_base import PSIDeviceBase
 from csaxs_bec.devices.epics.delay_generator_csaxs.delay_generator_csaxs import (
@@ -69,7 +71,7 @@ logger = bec_logger.logger
 # This can be adapted as needed, or fine-tuned per channel. On every reload of the
 # device configuration in BEC, these values will be set into the DDG1 device.
 _DEFAULT_CHANNEL_CONFIG: ChannelConfig = {
-    "amplitude": 5.0,
+    "amplitude": 4.5,
    "offset": 0.0,
    "polarity": OUTPUTPOLARITY.POSITIVE,
    "mode": "ttl",
@@ -131,6 +133,27 @@ class DDG1(PSIDeviceBase, DelayGeneratorCSAXS):
        device_manager (DeviceManagerBase | None, optional): Device manager. Defaults to None.
    """
    USER_ACCESS = ["keep_shutter_open_during_scan", "set_trigger"]
    # TODO Consider using the 'fsh' device instead.
    fast_shutter_readback = Cpt(
        EpicsSignalRO,
        read_pv="X12SA-ES1-TTL:INP_01",
        add_prefix=("",),  # Add this to prevent the prefix to be added to the signal
        kind=Kind.omitted,
        auto_monitor=True,
    )
    # The shutter control PV can indicate if the shutter is requested to be kept open. If that
    # is the case, we can not use the signal shutter_readback signal to check if the delay cycle
    # finishes but have to use the polling of the event status register to check if the burst finished.
    fast_shutter_control = Cpt(
        EpicsSignalRO,
        read_pv="X12SA-ES1-TTL:OUT_01",
        add_prefix=("",),  # Add this to prevent the prefix to be added to the signal
        kind=Kind.omitted,
        auto_monitor=True,
    )
    def __init__(
        self,
        name: str,
@@ -142,6 +165,7 @@ class DDG1(PSIDeviceBase, DelayGeneratorCSAXS):
        super().__init__(
            name=name, prefix=prefix, scan_info=scan_info, device_manager=device_manager, **kwargs
        )
        self._shutter_to_open_delay = 2e-3
        self.device_manager = device_manager
        self._poll_thread = threading.Thread(target=self._poll_event_status, daemon=True)
        self._poll_thread_run_event = threading.Event()
@@ -192,6 +216,21 @@ class DDG1(PSIDeviceBase, DelayGeneratorCSAXS):
        self.burst_delay.put(0)
        self.burst_count.put(1)
    def keep_shutter_open_during_scan(self, open: True) -> None:
        """
        Method to configure the delay generator for keeping the shutter open during a scans.
        This means that the additional delay to open the shutter needs to be removed (2e-3)
        from the timing of the signals.
        Args:
            open (bool): If True, the shutter will be kept open during the scan.
                         If False, the shutter will be opened and closed for each trigger cycle.
        """
        if open is True:
            self._shutter_to_open_delay = 0
        else:
            self._shutter_to_open_delay = 2e-3
    def on_stage(self) -> None:
        """
@@ -230,6 +269,18 @@ class DDG1(PSIDeviceBase, DelayGeneratorCSAXS):
        if self.burst_count.get() != 1:
            self.burst_count.put(1)
        #####################################
        ## Setup trigger source if needed ###
        #####################################
        # NOTE Some scans may change the trigger source to an external trigger,
        # so we will make sure that the default trigger source is set for the DDG1
        # before each scan. If a scan requires a different trigger source, i.e.
        # external triggers then the scan should implement this change after the
        # on_stage method was called.
        if self.trigger_source.get() != DEFAULT_TRIGGER_SOURCE:
            self.set_trigger(DEFAULT_TRIGGER_SOURCE)
        #########################################
        ### Setup timing for burst and delays ###
        #########################################
@@ -239,27 +290,34 @@ class DDG1(PSIDeviceBase, DelayGeneratorCSAXS):
        # Burst Period DDG1
        # Set burst_period to shutter width
-        # c/t0 + 2ms + exp_time * burst_count + 1ms
+        # c/t0 + self._shutter_to_open_delay + exp_time * burst_count
-        shutter_width = 2e-3 + exp_time * frames_per_trigger + 1e-3
+        shutter_width = (
            self._shutter_to_open_delay + exp_time * frames_per_trigger
        )  # Shutter starts closing at end of exposure
        if self.burst_period.get() != shutter_width:
            self.burst_period.put(shutter_width)
        # Trigger DDG2
        # a = t0 + 2ms, b = a + 1us
        # a has reference to t0, b has reference to a
-        # Add delay of 2ms to allow shutter to open
+        # Add delay of self._shutter_to_open_delay to allow shutter to open
-        self.set_delay_pairs(channel="ab", delay=2e-3, width=1e-6)
+        self.set_delay_pairs(channel="ab", delay=self._shutter_to_open_delay, width=1e-6)
        # Trigger shutter
-        # d = c/t0 + 2ms + exp_time * burst_count + 1ms
+        # d = c/t0 + self._shutter_to_open_delay + exp_time * burst_count + 1ms
        # c has reference to t0, d has reference to c
-        # Shutter opens without delay at t0, closes after exp_time * burst_count + 3ms (2ms open, 1ms close)
+        # Shutter opens without delay at t0, closes after exp_time * burst_count + 2ms (self._shutter_to_open_delay)
        self.set_delay_pairs(channel="cd", delay=0, width=shutter_width)
        self.set_delay_pairs(channel="gh", delay=self._shutter_to_open_delay, width=(shutter_width-self._shutter_to_open_delay))
        # Trigger extra pulse for MCS OR gate
        # f = e + 1us
        # e has refernce to d, f has reference to e
-        self.set_delay_pairs(channel="ef", delay=0, width=1e-6)
+        if self.scan_info.msg.scan_type == "fly":
            self.set_delay_pairs(channel="ef", delay=0, width=0)
        else:
            self.set_delay_pairs(channel="ef", delay=0, width=1e-6)
        # NOTE Add additional sleep to make sure that the IOC and DDG HW process the values properly
        # This value has been choosen empirically after testing with the HW. It's
@@ -431,7 +489,19 @@ class DDG1(PSIDeviceBase, DelayGeneratorCSAXS):
    def on_trigger(self) -> DeviceStatus:
        """
-        This method is called from BEC as a software trigger.
+        This method is called from BEC as a software trigger. Here the logic is as follows:
        We first check if the trigger_source is set to SINGLE_SHOT. Only then will we received,
        otherwise we return a status object directly as the DDG is triggered by an external
        source which will have to implement its own logic to wait for trigger signals to
        be received.
        I SINGLE_SHOT, the implementation here will send a software trigger. Now there are
        two options to wait for the trigger (burst) cycle to be done. One is to rely on the
        signal of the "mcs" card if it is present. However, this is only possible if the
        scan_type is not "fly" as in fly scans the ef channel is not triggered to send the last
        pulse to the card (but the card is finishing its acquisition in complete itself). Then
        we rely on the polling of the event status register to check if the burst cycle is done.
        It follows a specific procedure to ensure that the DDG1 and MCS card are properly handled
        on a trigger event. The established logic is as follows:
@@ -450,33 +520,46 @@ class DDG1(PSIDeviceBase, DelayGeneratorCSAXS):
        - Return the status object to BEC which will automatically resolve once the status register has
            the END_OF_BURST bit set. The callback of the status object will also stop the polling loop.
        """
        overall_start = time.time()
        self._stop_polling()
-        self._poll_thread_poll_loop_done.wait(timeout=1)
+
-        # NOTE: This sleep is important to ensure that the HW is ready to process new commands.
+        # NOTE If the trigger source is not SINGLE_SHOT, the DDG is triggered by an external source
-        # It has been empirically determined after long testing that this improves stability.
+        # thus we can not expect that trigger signals are meant to be awaited for. In this case,
-        time.sleep(0.02)
+        # we can directly return.
        if self.trigger_source.get() != TRIGGERSOURCE.SINGLE_SHOT.value:
            status = StatusBase(obj=self)
            status.set_finished()
            return status
        # NOTE If the MCS card is present in the current session of BEC,
        # we prepare the card for the next trigger. The procedure is implemented
-        # in the '_prepare_mcs_on_trigger' method.
+        # in the '_prepare_mcs_on_trigger' method. We will also use the mcs card
-        # Prepare the MCS card for the next software trigger
+        # to indicate when the burst cycle is done. If no mcs card is available
        # the fallback is to use the polling of the DDG
        mcs = self.device_manager.devices.get("mcs", None)
-        if mcs is None or mcs.enabled is False:
+        if mcs is None or mcs.enabled is False or self.scan_info.msg.scan_type == "fly":
-            logger.info("Did not find mcs card with name 'mcs' in current session")
+            self._poll_thread_poll_loop_done.wait(timeout=1)
            logger.warning("Did not find mcs card with name 'mcs' in current session")
            time.sleep(0.02)
            # Shutter is kept open, we can only rely on the event status register
            status = self._prepare_trigger_status_event()
            # Start polling thread again to monitor event status
            self._start_polling()
        else:
            start_time = time.time()
            logger.debug(f"Preparing mcs card ")
            status_mcs = self._prepare_mcs_on_trigger(mcs)
            # NOTE Timeout of 3s should be plenty, any longer wait should checked. If this happens to crash
            # an acquisition regularly with a WaitTimeoutError, the timeout can be increased but it should
            # be investigated why the EPICS interface is slow to respond.
            status_mcs.wait(timeout=3)
            status = TransitionStatus(mcs.acquiring, [ACQUIRING.ACQUIRING, ACQUIRING.DONE])
            logger.debug(f"Finished preparing mcs card {time.time()-start_time}")
-        # Prepare StatusBitsCompareStatus to resolve once the END_OF_BURST bit was set.
+        # Send trigger
        status = self._prepare_trigger_status_event()
        # Start polling thread again to monitor event status
        self._start_polling()
        # Trigger the DDG1
        self.trigger_shot.put(1, use_complete=True)
        self.cancel_on_stop(status)
        logger.info(f"Configured ddg in {time.time()-overall_start}")
        return status
    def on_stop(self) -> None:
--- a/csaxs_bec/devices/epics/delay_generator_csaxs/ddg_2.py
+++ b/csaxs_bec/devices/epics/delay_generator_csaxs/ddg_2.py
@@ -37,6 +37,7 @@ from csaxs_bec.devices.epics.delay_generator_csaxs.delay_generator_csaxs import
    ChannelConfig,
    DelayGeneratorCSAXS,
    LiteralChannels,
    BURSTCONFIG,
 )
 logger = bec_logger.logger
@@ -47,7 +48,7 @@ logger = bec_logger.logger
 # NOTE Default channel configuration for the DDG2 delay generator channels
 _DEFAULT_CHANNEL_CONFIG: ChannelConfig = {
-    "amplitude": 5.0,
+    "amplitude": 4.5,
    "offset": 0.0,
    "polarity": OUTPUTPOLARITY.POSITIVE,
    "mode": "ttl",
@@ -134,6 +135,9 @@ class DDG2(PSIDeviceBase, DelayGeneratorCSAXS):
        self.set_trigger(DEFAULT_TRIGGER_SOURCE)
        self.set_references_for_channels(DEFAULT_REFERENCES)
        # Set burst config
        self.burst_config.put(BURSTCONFIG.FIRST_CYCLE.value)
    def on_stage(self) -> DeviceStatus | StatusBase | None:
        """
--- a/csaxs_bec/devices/epics/delay_generator_csaxs/delay_generator_csaxs.py
+++ b/csaxs_bec/devices/epics/delay_generator_csaxs/delay_generator_csaxs.py
@@ -488,6 +488,7 @@ class DelayGeneratorCSAXS(Device):
        name="trigger_source",
        kind=Kind.omitted,
        doc="Trigger Source for the DDG, options in TRIGGERSOURCE",
        auto_monitor=True,
    )
    trigger_level = Cpt(
        EpicsSignal,
--- a/csaxs_bec/devices/epics/eps.py
+++ b/csaxs_bec/devices/epics/eps.py
@@ -0,0 +1,435 @@
 """EPS module for cSAXS beamline: defines the EPS device with its components and methods."""
 # fmt: off
 # Disable Black formatting for this file to preserve an easier readable structure for the component definitions.
 # pylint: disable=line-too-long
 from __future__ import annotations
 import time
 from bec_lib.logger import bec_logger
 from ophyd import Component as Cpt
 from ophyd import Device, EpicsSignal, EpicsSignalRO, Kind
 from ophyd_devices import PSIDeviceBase
 logger = bec_logger.logger
 # ---------------------------
 # Registry: sections/channels
 # ---------------------------
 class EPSSubDevices(Device):
    """Base class for EPS sub-device components (e.g. alarms, valves, shutters). with common methods if needed."""
    def describe(self) -> dict:
        desc = super().describe()
        for walk in self.walk_signals():
            if walk.item.attr_name not in desc:
                desc[walk.item.attr_name] = walk.item.describe()
        return desc
 class EPSAlarms(EPSSubDevices):
    """EPS alarms at the cSAXS beamline."""
    eps_alarm_cnt = Cpt(EpicsSignalRO, read_pv="X12SA-EPS-PLC:AlarmCnt_EPS", add_prefix=("",), name="eps_alarm_cnt", kind=Kind.omitted, doc="X12SA EPS Alarm count", auto_monitor=True, labels={"alarm"})
    mis_alarm_cnt = Cpt(EpicsSignalRO, read_pv="ARS00-MIS-PLC-01:AlarmCnt_Frontends", add_prefix=("",), name="mis_alarm_cnt", kind=Kind.omitted, doc="FrontEnd MIS Alarm count", auto_monitor=True, labels={"alarm"})
 class ValvesFrontend(EPSSubDevices):
    """Valves frontend at the cSAXS beamline."""
    fe_vvpg_0000 = Cpt(EpicsSignalRO, read_pv="X12SA-FE-VVPG-0000:PLC_OPEN", add_prefix=("",), name="fevvpg0000", kind=Kind.omitted, doc="FE-VVPG-0000", auto_monitor=True, labels={"valve"})
    fe_vvpg_1010 = Cpt(EpicsSignalRO, read_pv="X12SA-FE-VVPG-1010:PLC_OPEN", add_prefix=("",), name="fevvpg1010", kind=Kind.omitted, doc="FE-VVPG-1010", auto_monitor=True, labels={"valve"})
    fe_vvfv_2010 = Cpt(EpicsSignalRO, read_pv="X12SA-FE-VVFV-2010:PLC_OPEN", add_prefix=("",), name="fevvfv2010", kind=Kind.omitted, doc="FE-VVFV-2010", auto_monitor=True, labels={"valve"})
    fe_vvpg_2010 = Cpt(EpicsSignalRO, read_pv="X12SA-FE-VVPG-2010:PLC_OPEN", add_prefix=("",), name="fevvpg2010", kind=Kind.omitted, doc="FE-VVPG-2010", auto_monitor=True, labels={"valve"})
 class ValvesOptics(EPSSubDevices):
    """Valves at the optics hutch."""
    op_vvpg_1010 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-VVPG-1010:PLC_OPEN", add_prefix=("",), name="opvvpg1010", kind=Kind.omitted, doc="OP-VVPG-1010", auto_monitor=True, labels={"valve"})
    op_vvpg_2010 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-VVPG-2010:PLC_OPEN", add_prefix=("",), name="opvvpg2010", kind=Kind.omitted, doc="OP-VVPG-2010", auto_monitor=True, labels={"valve"})
    op_vvpg_3010 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-VVPG-3010:PLC_OPEN", add_prefix=("",), name="opvvpg3010", kind=Kind.omitted, doc="OP-VVPG-3010", auto_monitor=True, labels={"valve"})
    op_vvpg_3020 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-VVPG-3020:PLC_OPEN", add_prefix=("",), name="opvvpg3020", kind=Kind.omitted, doc="OP-VVPG-3020", auto_monitor=True, labels={"valve"})
    op_vvpg_4010 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-VVPG-4010:PLC_OPEN", add_prefix=("",), name="opvvpg4010", kind=Kind.omitted, doc="OP-VVPG-4010", auto_monitor=True, labels={"valve"})
    op_vvpg_5010 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-VVPG-5010:PLC_OPEN", add_prefix=("",), name="opvvpg5010", kind=Kind.omitted, doc="OP-VVPG-5010", auto_monitor=True, labels={"valve"})
    op_vvpg_6010 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-VVPG-6010:PLC_OPEN", add_prefix=("",), name="opvvpg6010", kind=Kind.omitted, doc="OP-VVPG-6010", auto_monitor=True, labels={"valve"})
    op_vvpg_7010 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-VVPG-7010:PLC_OPEN", add_prefix=("",), name="opvvpg7010", kind=Kind.omitted, doc="OP-VVPG-7010", auto_monitor=True, labels={"valve"})
 class ValvesEndstation(EPSSubDevices):
    """Endstation valves at the cSAXS beamline."""
    es_vvpg_1010 = Cpt(EpicsSignalRO, read_pv="X12SA-ES-VVPG-1010:PLC_OPEN", add_prefix=("",), name="esvvpg1010", kind=Kind.omitted, doc="ES-VVPG-1010", auto_monitor=True, labels={"valve"})
 class ShuttersFrontend(EPSSubDevices):
    """Shutters frontend."""
    fe_psh1 = Cpt(EpicsSignalRO, read_pv="X12SA-FE-PSH1-EMLS-0010:OPEN", add_prefix=("",), name="fepsh1", kind=Kind.omitted, doc="FE-PSH1-EMLS-0010", auto_monitor=True, labels={"shutter"})
    fe_sto1 = Cpt(EpicsSignalRO, read_pv="X12SA-FE-STO1-EMLS-0010:OPEN", add_prefix=("",), name="festo1", kind=Kind.omitted, doc="FE-STO1-EMLS-0010", auto_monitor=True, labels={"shutter"})
 class ShuttersEndstation(EPSSubDevices):
    """Shutters at the endstation."""
    es_psh17010 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-PSH1-EMLS-7010:OPEN", add_prefix=("",), name="espsh17010", kind=Kind.omitted, doc="OP-PSH1-EMLS-7010", auto_monitor=True, labels={"shutter"})
 class DMMMonochromator(EPSSubDevices):
    """DMM monochromator signals at the cSAXS beamline."""
    dmm_temp_surface_1 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-ETTC-3010:TEMP", add_prefix=("",), name="dmm_temp_surface_1", kind=Kind.omitted, doc="DMM Temp Surface 1", auto_monitor=True, labels={"temp"})
    dmm_temp_surface_2 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-ETTC-3020:TEMP", add_prefix=("",), name="dmm_temp_surface_2", kind=Kind.omitted, doc="DMM Temp Surface 2", auto_monitor=True, labels={"temp"})
    dmm_temp_shield_1_disaster = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-ETTC-3030:TEMP", add_prefix=("",), name="dmm_temp_shield_1_disaster", kind=Kind.omitted, doc="DMM Temp Shield 1 (disaster)", auto_monitor=True, labels={"temp"})
    dmm_temp_shield_2_disaster = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-ETTC-3040:TEMP", add_prefix=("",), name="dmm_temp_shield_2_disaster", kind=Kind.omitted, doc="DMM Temp Shield 2 (disaster)", auto_monitor=True, labels={"temp"})
    dmm_translation_thru = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-EMLS-3010:THRU", add_prefix=("",), name="dmm_translation_thru", kind=Kind.omitted, doc="DMM Translation ThruPos", auto_monitor=True, labels={"switch"})
    dmm_translation_in = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-EMLS-3020:IN", add_prefix=("",), name="dmm_translation_in", kind=Kind.omitted, doc="DMM Translation InPos", auto_monitor=True, labels={"switch"})
    dmm_bragg_thru = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-EMLS-3030:THRU", add_prefix=("",), name="dmm_bragg_thru", kind=Kind.omitted, doc="DMM Bragg ThruPos", auto_monitor=True, labels={"switch"})
    dmm_bragg_in = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-EMLS-3040:IN", add_prefix=("",), name="dmm_bragg_in", kind=Kind.omitted, doc="DMM Bragg InPos", auto_monitor=True, labels={"switch"})
    dmm_heater_fault_xtal_1 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-EMSW-3050:SWITCH", add_prefix=("",), name="dmm_heater_fault_xtal_1", kind=Kind.omitted, doc="DMM Heater Fault XTAL 1", auto_monitor=True, labels={"fault"})
    dmm_heater_fault_xtal_2 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-EMSW-3060:SWITCH", add_prefix=("",), name="dmm_heater_fault_xtal_2", kind=Kind.omitted, doc="DMM Heater Fault XTAL 2", auto_monitor=True, labels={"fault"})
    dmm_heater_fault_support_1 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM-EMSW-3070:SWITCH", add_prefix=("",), name="dmm_heater_fault_support_1", kind=Kind.omitted, doc="DMM Heater Fault Support 1", auto_monitor=True, labels={"fault"})
    dmm_energy = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM1:ENERGY-GET", add_prefix=("",), name="dmm_energy", kind=Kind.omitted, doc="DMM Energy", auto_monitor=True, labels={"energy"})
    dmm_position = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM1:POSITION", add_prefix=("",), name="dmm_position", kind=Kind.omitted, doc="DMM Position", auto_monitor=True, labels={"string"})
    dmm_stripe = Cpt(EpicsSignalRO, read_pv="X12SA-OP-DMM1:STRIPE", add_prefix=("",), name="dmm_stripe", kind=Kind.omitted, doc="DMM Stripe", auto_monitor=True, labels={"string"})
 class CCMMonochromator(EPSSubDevices):
    """CCM monochromator signals at the cSAXS beamline."""
    ccm_temp_crystal = Cpt(EpicsSignalRO, read_pv="X12SA-OP-CCM-ETTC-4010:TEMP", add_prefix=("",), name="ccm_temp_crystal", kind=Kind.omitted, doc="CCM Temp Crystal", auto_monitor=True, labels={"temp"})
    ccm_temp_shield_disaster = Cpt(EpicsSignalRO, read_pv="X12SA-OP-CCM-ETTC-4020:TEMP", add_prefix=("",), name="ccm_temp_shield_disaster", kind=Kind.omitted, doc="CCM Temp Shield (disaster)", auto_monitor=True, labels={"temp"})
    ccm_heater_fault_1 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-CCM-EMSW-4010:SWITCH", add_prefix=("",), name="ccm_heater_fault_1", kind=Kind.omitted, doc="CCM Heater Fault 1", auto_monitor=True, labels={"fault"})
    ccm_heater_fault_2 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-CCM-EMSW-4020:SWITCH", add_prefix=("",), name="ccm_heater_fault_2", kind=Kind.omitted, doc="CCM Heater Fault 2", auto_monitor=True, labels={"fault"})
    ccm_heater_fault_3 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-CCM-EMSW-4030:SWITCH", add_prefix=("",), name="ccm_heater_fault_3", kind=Kind.omitted, doc="CCM Heater Fault 3", auto_monitor=True, labels={"fault"})
    ccm_energy = Cpt(EpicsSignalRO, read_pv="X12SA-OP-CCM1:ENERGY-GET", add_prefix=("",), name="ccm_energy", kind=Kind.omitted, doc="CCM Energy", auto_monitor=True, labels={"energy"})
    ccm_position = Cpt(EpicsSignalRO, read_pv="X12SA-OP-CCM1:POSITION", add_prefix=("",), name="ccm_position", kind=Kind.omitted, doc="CCM Position", auto_monitor=True, labels={"string"})
 class CoolingWater(EPSSubDevices):
    """Cooling water signals at the cSAXS beamline."""
    op_sl1_efsw_2010_flow = Cpt(EpicsSignalRO, read_pv="X12SA-OP-SL1-EFSW-2010:FLOW", add_prefix=("",), name="op_sl1_efsw_2010_flow", kind=Kind.omitted, doc="OP-SL1-EFSW-2010", auto_monitor=True, labels={"flow"})
    op_sl2_efsw_2010_flow = Cpt(EpicsSignalRO, read_pv="X12SA-OP-SL2-EFSW-2010:FLOW", add_prefix=("",), name="op_sl2_efsw_2010_flow", kind=Kind.omitted, doc="OP-SL2-EFSW-2010", auto_monitor=True, labels={"flow"})
    op_eb1_efsw_5010_flow = Cpt(EpicsSignalRO, read_pv="X12SA-OP-EB1-EFSW-5010:FLOW", add_prefix=("",), name="op_eb1_efsw_5010_flow", kind=Kind.omitted, doc="OP-EB1-EFSW-5010", auto_monitor=True, labels={"flow"})
    op_eb1_efsw_5020_flow = Cpt(EpicsSignalRO, read_pv="X12SA-OP-EB1-EFSW-5020:FLOW", add_prefix=("",), name="op_eb1_efsw_5020_flow", kind=Kind.omitted, doc="OP-EB1-EFSW-5020", auto_monitor=True, labels={"flow"})
    op_sl3_efsw_5010_flow = Cpt(EpicsSignalRO, read_pv="X12SA-OP-SL3-EFSW-5010:FLOW", add_prefix=("",), name="op_sl3_efsw_5010_flow", kind=Kind.omitted, doc="OP-SL3-EFSW-5010", auto_monitor=True, labels={"flow"})
    op_kb_efsw_6010_flow = Cpt(EpicsSignalRO, read_pv="X12SA-OP-KB-EFSW-6010:FLOW", add_prefix=("",), name="op_kb_efsw_6010_flow", kind=Kind.omitted, doc="OP-KB-EFSW-6010", auto_monitor=True, labels={"flow"})
    op_psh1_efsw_7010_flow = Cpt(EpicsSignalRO, read_pv="X12SA-OP-PSH1-EFSW-7010:FLOW", add_prefix=("",), name="op_psh1_efsw_7010_flow", kind=Kind.omitted, doc="OP-PSH1-EFSW-7010", auto_monitor=True, labels={"flow"})
    es_eb2_efsw_1010_flow = Cpt(EpicsSignalRO, read_pv="X12SA-ES-EB2-EFSW-1010:FLOW", add_prefix=("",), name="es_eb2_efsw_1010_flow", kind=Kind.omitted, doc="ES-EB2-EFSW-1010", auto_monitor=True, labels={"flow"})
    op_cs_ecvw_0010 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-CS-ECVW-0010:PLC_OPEN", add_prefix=("",), name="op_cs_ecvw_0010", kind=Kind.omitted, doc="OP-CS-ECVW-0010", auto_monitor=True, labels={"valve"})
    op_cs_ecvw_0020 = Cpt(EpicsSignalRO, read_pv="X12SA-OP-CS-ECVW-0020:PLC_OPEN", add_prefix=("",), name="op_cs_ecvw_0020", kind=Kind.omitted, doc="OP-CS-ECVW-0020", auto_monitor=True, labels={"valve"})
 class EPS(PSIDeviceBase):
    """EPS device for the cSAXS beamline."""
    USER_ACCESS = [
        "show_all",
        "water_cooling_op",
    ]
    alarms = Cpt(EPSAlarms, name="alarms", doc="EPS Alarms")
    valves_frontend = Cpt(ValvesFrontend, name="valves_frontend", doc="Valves Frontend")
    valves_optics = Cpt(ValvesOptics, name="valves_optics", doc="Valves Optics Hutch")
    valves_es = Cpt(ValvesEndstation, name="valves_es", doc="Valves ES Hutch")
    shutters_frontend = Cpt(ShuttersFrontend, name="shutters_frontend", doc="Shutters Frontend")
    shutters_es = Cpt(ShuttersEndstation, name="shutters_es", doc="Shutters Endstation")
    dmm_monochromator = Cpt(DMMMonochromator, name="dmm_monochromator", doc="DMM Monochromator")
    ccm_monochromator = Cpt(CCMMonochromator, name="ccm_monochromator", doc="CCM Monochromator")
    cooling_water = Cpt(CoolingWater, name="cooling_water", doc="Cooling Water")
    # Acknowledgment signals for PLC communication (if needed for future use)
    ackerr = Cpt(EpicsSignal, read_pv="X12SA-EPS-PLC:ACKERR-REQUEST", add_prefix=("",), name="ackerr", kind=Kind.omitted, doc="ACKERR request - OP-CS-ECVW-0020", auto_monitor=True, labels={"request"})
    request = Cpt(EpicsSignal, read_pv="X12SA-OP-CS-ECVW:PLC_REQUEST", add_prefix=("",), name="op_cs_ecvw_request", kind=Kind.omitted, doc="PLC request - OP-CS-ECVW-PLC_REQUEST", auto_monitor=True, labels={"request"})
    def _notify(self, msg: str, show_as_client_msg: bool = True):
        """Utility method to print a message, and optionally send it to the client UI if it should be shown also as a client message."""
        try:
            if show_as_client_msg:
                self.device_manager.connector.send_client_info(msg, scope="", show_asap=True)
            else:
                print(msg)
        except Exception:
            logger.error(f"Failed to send client message, falling back to print: {msg}")
            print(str(msg))
    # ----------------------------------------------------------
    # Water cooling operation
    # ----------------------------------------------------------
    def safe_get(self, sig, default=None):
        """Helper method to safely get a signal value, returning a default if there's an error."""
        try:
            return sig.get()
        except Exception as ex:
            logger.warning(f"Failed to get signal {sig.pvname}: {ex}")
            return default
    def water_cooling_op(self):
        """
        Open ECVW valves, reset EPS alarms, monitor for 20s,
        then ensure stability (valves remain open) for 10s.
        All messages sent to client.
        """
        POLL_PERIOD = 2
        TIMEOUT = 20
        STABILITY = 15
        self._notify("=== Water Cooling Operation ===")
        # --- Signals ---
        eps_alarm_sig = self.alarms.eps_alarm_cnt
        ackerr = self.ackerr
        request = self.request
        valves = [self.cooling_water.op_cs_ecvw_0010, self.cooling_water.op_cs_ecvw_0020]
        # Flow channels list extracted from CHANNELS
        flow_items = [walk.item for walk in self.cooling_water.walk_signals() if "flow" in walk.item._ophyd_labels_]
        # --- Step 1: EPS alarm reset ---
        alarm_value = self.safe_get(eps_alarm_sig, 0)
        if alarm_value and alarm_value > 0:
            self._notify(f"[WaterCooling] EPS alarms present ({alarm_value}) → resetting…")
            try:
                ackerr.put(1)
            except Exception as ex:
                self._notify(f"[WaterCooling] WARNING: ACKERR write failed: {ex}")
            time.sleep(0.3)
        else:
            self._notify("[WaterCooling] No EPS alarms detected.")
        # --- Step 2: Issue open request ---
        self._notify("[WaterCooling] Sending cooling-valve OPEN request…")
        try:
            request.put(1)
        except Exception as ex:
            self._notify(f"[WaterCooling] ERROR: Failed to send OPEN request: {ex}")
            return False
        # --- Step 3: Monitoring loop (clean client table output) ---
        start = time.time()
        end = start + TIMEOUT
        stable_until = None
        # Print (server-side) header once
        print("Monitoring valves and flow sensors...")
        print(f"  Valves: {valves[0].attr_name[-4:]}, {valves[1].attr_name[-4:]}")
        print(f"  Note: stability requires valves to remain OPEN for {STABILITY} seconds.")
        # One table header to the client (via device manager)
        # Fixed-width columns for alignment in monospaced UI
        table_header = f"{'Time':>6} | {'Valves':<21} | {'Flows (OK/FAIL/N/A)':<20}"
        self._notify(table_header)
        def snapshot():
            # Valve snapshot
            v_states = [self.safe_get(v, None) for v in valves]
            v1 = f"{valves[0].attr_name[-4:]}=" + ("OPEN  " if v_states[0] is True or v_states[0] == 1 else "CLOSED" if v_states[0] is False or v_states[0] == 0 else "N/A  ")
            v2 = f"{valves[1].attr_name[-4:]}=" + ("OPEN  " if v_states[1] is True or v_states[1] == 1 else "CLOSED" if v_states[1] is False or v_states[1] == 0 else "N/A  ")
            # 2 valves with a single space between => width ~ 21
            valve_str = f"{v1} {v2}"
            # Flow summary: OK/FAIL/N/A counts (compact)
            flow_states = []
            for fsig in flow_items:
                fval = self.safe_get(fsig, None)
                flow_states.append(True if fval in (1, True) else False if fval in (0, False) else None)
            ok = sum(1 for f in flow_states if f is True)
            fail = sum(1 for f in flow_states if f is False)
            na = sum(1 for f in flow_states if f is None)
            flow_summary = f"{ok:>2} / {fail:>2} / {na:>2}"
            return v_states, valve_str, flow_summary
        while True:
            # TODO Consider adding a timeout to avoid infinite loop.
            now = time.time()
            elapsed = int(now - start)
            if now > end:
                # One last line to client
                v_states, valves_s, flows_s = snapshot()
                self._notify(f"{elapsed:>6}s | {valves_s:<21} | {flows_s:<20}")
                print("→ TIMEOUT: Cooling valves failed to remain OPEN.")
                return False
            # Live snapshot
            v_states, valves_s, flows_s = snapshot()
            # Exactly one concise line to client per cycle
            self._notify(f"{elapsed:>6}s | {valves_s:<21} | {flows_s:<20}")
            both_open = all(s is not None and bool(s) for s in v_states)
            if both_open:
                if stable_until is None:
                    stable_until = now + STABILITY
                    print(f"[WaterCooling] Both valves OPEN → starting {STABILITY}s stability window…")
                else:
                    if now >= stable_until:
                        print("→ SUCCESS: Valves remained OPEN during stability window.")
                        return True
            else:
                if stable_until is not None:
                    print("[WaterCooling] Valve closed again → restarting stability window.")
                stable_until = None
            time.sleep(POLL_PERIOD)
    def show_all(self):
        red = "\x1b[91m"
        green = "\x1b[92m"
        white = "\x1b[0m"
        bold = "\x1b[1m"
        cyan = "\x1b[96m"
        # ---- New: enum maps for numeric -> string rendering ----
        POSITION_ENUM = {0: "out of beam", 1: "in beam"}
        STRIPE_ENUM = {0: "Stripe 1 W/B4C", 1: "Stripe 2 NiV/B4C"}
        POSITION_ATTRS = {self.dmm_monochromator.dmm_position.attr_name, self.ccm_monochromator.ccm_position.attr_name}
        STRIPE_ATTRS = {self.dmm_monochromator.dmm_stripe.attr_name}
        def is_bool_like(v):
            return isinstance(v, (bool, int)) and v in (0, 1, True, False)
        # ---- Changed: accept attr in formatter so we can apply enum mapping ----
        def fmt_value(value: any, signal: EpicsSignalRO):
            if value is None:
                return f"{red}MISSING{white}"
            attr = signal.attr_name
            # ---------- Explicit enum mappings by attribute ----------
            if attr in POSITION_ATTRS:
                # Position comes as numeric 0/1
                try:
                    iv = int(value)
                    return POSITION_ENUM.get(iv, f"{iv}")
                except Exception:
                    # Fallback if it’s already a string or unexpected
                    return f"{value}"
            if attr in STRIPE_ATTRS:
                # Stripe comes as numeric 0/1
                try:
                    iv = int(value)
                    return STRIPE_ENUM.get(iv, f"{iv}")
                except Exception:
                    return f"{value}"
            # ------------------- TEMPERATURE -------------------
            if "temp" in signal._ophyd_labels_ and isinstance(value, (int, float)):
                return f"{value:.1f}"
            # ------------------- ENERGY ------------------------
            if "energy" in signal._ophyd_labels_ and isinstance(value, (int, float)):
                return f"{value:.4f}"
            # ------------------- STRINGS -----------------------
            if "string" in signal._ophyd_labels_ or "position" in signal._ophyd_labels_:
                # For other strings, just echo the value
                return f"{value}"
            # ------------------- SWITCH (ACTIVE/INACTIVE) ------
            if "switch" in signal._ophyd_labels_ and is_bool_like(value):
                return f"{green+'ACTIVE'+white if value else red+'INACTIVE'+white}"
            # ------------------- FAULT (OK/FAULT) --------------
            if "fault" in signal._ophyd_labels_ and is_bool_like(value):
                return f"{green+'OK'+white if not value else red+'FAULT'+white}"
            # ------------------- VALVE/SHUTTER -----------------
            if ("valve" in signal._ophyd_labels_ or "shutter" in signal._ophyd_labels_) and is_bool_like(value):
                return f"{green+'OPEN'+white if value else red+'CLOSED'+white}"
            # ------------------- FLOW (OK/FAIL) ----------------
            if "flow" in signal._ophyd_labels_ and is_bool_like(value):
                return f"{green}OK{white}" if bool(value) else f"{red}FAIL{white}"
            # ------------------- FALLBACK -----------------------
            return f"{value}"
        # ------------------- PRINT START ---------------------
        print(f"{bold}X12SA EPS status{white}")
        for name, component in self._sig_attrs.items():
            sub_device = getattr(self, name)
            rows = []
            # Only print sub-devices, not individual request signals
            if not isinstance(sub_device, Device):
                continue
            print(f"\n{bold}{component.doc}{white}")
            for sub_walk in sub_device.walk_components():
                cpt: Cpt = sub_walk.item
                it: EpicsSignalRO = getattr(sub_device, cpt.attr)
                val = self.safe_get(it)
                rows.append((cpt.doc, val, it))
            label_width = max(32, *(len(label) for (label, _, _) in rows))
            for label, value, it in rows:
                fv = fmt_value(value, it)  # <-- pass attr to formatter
                print(f"  - {label:<{label_width}} {fv}")
            if sub_device.attr_name == "cooling_water":
                v1 = self.safe_get(self.cooling_water.op_cs_ecvw_0010)
                v2 = self.safe_get(self.cooling_water.op_cs_ecvw_0020)
                def closed(v):
                    return is_bool_like(v) and not bool(v)
                if closed(v1) and closed(v2):
                    print(f"\n{cyan}Hint:{white} Both water cooling valves are CLOSED.\n" f"You can open them using: {bold}dev.x12saEPS.water_cooling_op(){white}")
 # fmt: on
 # ----------------------------------------------------------
 # Consistency report
 # ----------------------------------------------------------
 # def consistency_report(self, *, verbose=True):
 #     missing = []
 #     dupes = []
 #     seen = {}
 #     for sub_device in self.walk_components():
 #         section = sub_device.name
 #         for walk in sub_device.walk_components():
 #             cpt: Cpt = walk.ancestors[-1]
 #             it: EpicsSignalRO = walk.item
 #             if not hasattr(self, it["attr"]):
 #                 missing.append((section, it["attr"], it["label"], it["pv"]))
 #             pv = it["pv"]
 #             if pv in seen:
 #                 dupes.append((pv, seen[pv], (section, it["attr"], it["label"])))
 #             else:
 #                 seen[pv] = (section, it["attr"], it["label"])
 #     if verbose:
 #         print("=== Consistency Report ===")
 #         if missing:
 #             print("\nMissing attributes:")
 #             for sec, a, lbl, pv in missing:
 #                 print(f"  - [{sec}] {a} {lbl} pv={pv}")
 #         else:
 #             print("\nNo missing attributes.")
 #         if dupes:
 #             print("\nDuplicate PVs:")
 #             for pv, f1, f2 in dupes:
 #                 print(f"  {pv} → {f1} AND {f2}")
 #         else:
 #             print("\nNo duplicate PVs.")
 #     return {"missing_attrs": missing, "duplicate_pvs": dupes}
--- a/csaxs_bec/devices/epics/fast_shutter.py
+++ b/csaxs_bec/devices/epics/fast_shutter.py
@@ -0,0 +1,67 @@
 """
 Shutter device for the cSAXS beamline with 2 PVs. One is connected to a
 signal can be set to control the shutter signal, and the other is a readback signal
 that can be monitored to check the shutter status as it may be controlled directly by
 the delay generator."""
 from ophyd import Component as Cpt
 from ophyd import Device, EpicsSignal, EpicsSignalRO, Kind
 class cSAXSFastEpicsShutter(Device):
    """
    Fast EPICS shutter with automatic PV selection based on host subnet. IOC prefix is 'X12SA-ES1-TTL:'
    """
    USER_ACCESS = ["fshopen", "fshclose", "fshstatus", "fshinfo", "fshstatus_readback", "help"]
    SUB_VALUE = "value"
    _default_sub = SUB_VALUE
    # PVs
    shutter = Cpt(EpicsSignal, "OUT_01", kind=Kind.normal, auto_monitor=True)
    shutter_readback = Cpt(EpicsSignalRO, "INP_01", kind=Kind.normal, auto_monitor=True)
    # -----------------------------------------------------
    # User-facing shutter control functions
    # -----------------------------------------------------
    # pylint: disable=protetced-access
    def fshopen(self) -> None:
        """Open the fast shutter."""
        self.shutter.set(1).wait(timeout=self.shutter._timeout)  # 2s default for ES
    # pylint: disable=protetced-access
    def fshclose(self) -> None:
        """Close the fast shutter."""
        self.shutter.set(0).wait(timeout=self.shutter._timeout)  # 2s default for ES
    def fshstatus(self) -> int:
        """Return the fast shutter control status (0=closed, 1=open)."""
        return self.shutter.get()  # Ensure we have the latest value from EPICS
    def fshstatus_readback(self) -> int:
        """Return the fast shutter status (0=closed, 1=open)."""
        return self.shutter_readback.get()  # Ensure we have the latest value from EPICS
    def fshinfo(self) -> None:
        """Print information about which EPICS PV channel is being used."""
        pvname = self.shutter.pvname
        shutter_readback_pvname = self.shutter_readback.pvname
        print(
            f"Fast shutter connected to EPICS channel: {pvname} with shutter readback: {shutter_readback_pvname}"
        )
    def stop(self, *, success: bool = False) -> None:
        """Stop the shutter device. Make sure to close it."""
        self.shutter.put(0)
        super().stop(success=success)
    def help(self):
        """Display available user methods."""
        print("Available methods:")
        for method in self.USER_ACCESS:
            print(f"  - {method}")
 if __name__ == "__main__":
    fsh = cSAXSFastEpicsShutter(name="fsh", prefix="X12SA-ES1-TTL:")
--- a/csaxs_bec/devices/epics/mcs_card/mcs_card_csaxs.py
+++ b/csaxs_bec/devices/epics/mcs_card/mcs_card_csaxs.py
@@ -22,7 +22,13 @@ import numpy as np
 from bec_lib.logger import bec_logger
 from ophyd import Component as Cpt
 from ophyd import EpicsSignalRO, Kind
-from ophyd_devices import AsyncMultiSignal, CompareStatus, ProgressSignal, StatusBase
+from ophyd_devices import (
    AsyncMultiSignal,
    CompareStatus,
    ProgressSignal,
    StatusBase,
    TransitionStatus,
 )
 from ophyd_devices.interfaces.base_classes.psi_device_base import PSIDeviceBase
 from csaxs_bec.devices.epics.mcs_card.mcs_card import (
@@ -255,6 +261,7 @@ class MCSCardCSAXS(PSIDeviceBase, MCSCard):
            **kwargs: Additional keyword arguments from the subscription, including 'obj' (the EpicsSignalRO instance).
        """
        with self._rlock:
            logger.info(f"Received update on mcs card {self.name}")
            if self._omit_mca_callbacks.is_set():
                return  # Suppress callbacks when erasing all channels
            self._mca_counter_index += 1
@@ -286,7 +293,7 @@ class MCSCardCSAXS(PSIDeviceBase, MCSCard):
            )
            # Once we have received all channels, push data to BEC and reset for next accumulation
-            logger.debug(
+            logger.info(
                f"Received update for {attr_name}, index {self._mca_counter_index}/{self.NUM_MCA_CHANNELS}"
            )
            if len(self._current_data) == self.NUM_MCA_CHANNELS:
@@ -310,10 +317,14 @@ class MCSCardCSAXS(PSIDeviceBase, MCSCard):
            old_value: Previous value of the signal.
            value: New value of the signal.
        """
-        scan_done = bool(value == self._num_total_triggers)
+        try:
-        self.progress.put(value=value, max_value=self._num_total_triggers, done=scan_done)
+            scan_done = bool(value == self._num_total_triggers)
-        if scan_done:
+            self.progress.put(value=value, max_value=self._num_total_triggers, done=scan_done)
-            self._scan_done_event.set()
+            if scan_done:
                self._scan_done_event.set()
        except Exception:
            content = traceback.format_exc()
            logger.info(f"Device {self.name}  error: {content}")
    def on_stage(self) -> None:
        """
@@ -363,7 +374,10 @@ class MCSCardCSAXS(PSIDeviceBase, MCSCard):
        self._num_total_triggers = triggers * num_points
        self._acquisition_group = "monitored" if triggers == 1 else "burst_group"
        self.preset_real.set(0).wait(timeout=self._pv_timeout)
-        self.num_use_all.set(triggers).wait(timeout=self._pv_timeout)
+        if self.scan_info.msg.scan_type == "step":
            self.num_use_all.set(triggers).wait(timeout=self._pv_timeout)
        elif self.scan_info.msg.scan_type == "fly":
            self.num_use_all.set(self._num_total_triggers).wait(timeout=self._pv_timeout)
        # Clear any previous data, just to be sure
        with self._rlock:
@@ -385,6 +399,21 @@ class MCSCardCSAXS(PSIDeviceBase, MCSCard):
        self._omit_mca_callbacks.clear()
        logger.info(f"MCS Card {self.name} on_stage completed in {time.time() - start_time:.3f}s.")
        # For a fly scan we need to start the mcs card ourselves
        if self.scan_info.msg.scan_type == "fly":
            self.erase_start.put(1)
    def on_prescan(self) -> None | StatusBase:
        """
        This method is called after on_stage and before the scan starts. For the MCS card, we need to make sure
        that the card is properly started for fly scans. For step scans, this will be handled by the DDG,
        so no action is required here.
        """
        if self.scan_info.msg.scan_type == "fly":
            status_acquiring = CompareStatus(self.acquiring, ACQUIRING.ACQUIRING)
            self.cancel_on_stop(status_acquiring)
            return status_acquiring
        return None
    def on_unstage(self) -> None:
        """
@@ -422,9 +451,16 @@ class MCSCardCSAXS(PSIDeviceBase, MCSCard):
                        hasattr(self.scan_info.msg, "num_points")
                        and self.scan_info.msg.num_points is not None
                    ):
-                        if self._current_data_index == self.scan_info.msg.num_points:
+                        if self.scan_info.msg.scan_type == "step":
-                            for callback in self._scan_done_callbacks:
+                            if self._current_data_index == self.scan_info.msg.num_points:
-                                callback(exception=None)
+                                for callback in self._scan_done_callbacks:
                                    callback(exception=None)
                        else:
                            logger.info(f"Current data index is {self._current_data_index}")
                            if self._current_data_index >= 1:
                                for callback in self._scan_done_callbacks:
                                    callback(exception=None)
                    time.sleep(0.02)  # 20ms delay to avoid busy loop
                except Exception as exc:  # pylint: disable=broad-except
                    content = traceback.format_exc()
@@ -452,7 +488,6 @@ class MCSCardCSAXS(PSIDeviceBase, MCSCard):
        """Callback for status failure, the monitoring thread should be stopped."""
        # NOTE Check for status.done and status.success is important to avoid
        if status.done:
            self._start_monitor_async_data_emission.clear()  # Stop monitoring
    def on_complete(self) -> CompareStatus:
@@ -478,6 +513,13 @@ class MCSCardCSAXS(PSIDeviceBase, MCSCard):
            monitoring thread is stopped properly.
        """
        # NOTE For fly scans with EXT/EN enabled triggering, the MCS card needs to receive an
        # additional trigger at the end of the scan to advance the channel. This will ensure
        # that the acquisition finishes on the card and that data is emitted to BEC. If the acquisition
        # was already finished (i.e. normal step scan sends 1 extra pulse per burst cycle), this will
        # not have any effect as the card will already be in DONE state and signal.
        self.software_channel_advance.put(1)
        # Prepare and register status callback for the async monitoring loop
        status_async_data = StatusBase(obj=self)
        self._scan_done_callbacks.append(partial(self._status_callback, status_async_data))
@@ -491,7 +533,7 @@ class MCSCardCSAXS(PSIDeviceBase, MCSCard):
        # Combine both statuses
        ret_status = status & status_async_data
-        # Handle external stop/cancel, and stop monitoring
+        # NOTE: Handle external stop/cancel, and stop monitoring
        ret_status.add_callback(self._status_failed_callback)
        self.cancel_on_stop(ret_status)
        return ret_status
--- a/csaxs_bec/devices/jungfraujoch/README.MD
+++ b/csaxs_bec/devices/jungfraujoch/README.MD
@@ -0,0 +1,48 @@
 # Overview
 Integration module for Eiger detectors at the cSAXS beamline with JungfrauJoch backend.
 There are currently two supported Eiger detectors:
 - EIGER 1.5M
 - EIGER 9M
 This module provides a base integration for both detectors. A short list of useful
 information is also provided below.
 ## JungfrauJoch Service
 The JungfrauJoch WEB UI is available on http://sls-jfjoch-001:8080. This is an interface
 to the broker which runs on sls-jfjoch-001.psi.ch. The writer service runs on
 xbl-daq-34.psi.ch. Permissions to get access to these machines and run systemctl or
 journalctl commands can be requested with the Infrastructure and Services group in AWI.
 Beamline scientists need to check if they have the necessary permissions to connect
 to these machines and run the commands below.
 Useful commands for the broker service on sls-jfjoch-001.psi.ch:
 - sudo systemctl status jfjoch_broker # Check status
 - sudo systemctl start jfjoch_broker # Start service
 - sudo systemctl stop jfjoch_broker # Stop service
 - sudo systemctl restart jfjoch_broker # Restart service
 For the writer service on xbl-daq-34.psi.ch:
 - sudo journalctl -u jfjoch_writer -f # streams live logs
 - sudo systemctl status jfjoch_writer # Check status
 - sudo systemctl start jfjoch_writer # Start service
 - sudo systemctl stop jfjoch_writer # Stop service
 - sudo systemctl restart jfjoch_writer # Restart service
 More information about the JungfrauJoch and API client can be found at: (https://jungfraujoch.readthedocs.io/en/latest/index.html)
 ### JungfrauJoch API Client
 A thin wrapper for the JungfrauJoch API client is provided in the [jungfrau_joch_client](./jungfrau_joch_client.py). 
 Details about the specific integration are provided in the code. 
 ## Eiger implementation
 The Eiger detector integration is provided in the [eiger.py](./eiger.py) module. It provides a base integration for both Eiger 1.5M and Eiger 9M detectors.
 Logic specific to each detector is implemented in the respective modules:
 - [eiger_1_5m.py](./eiger_1_5m.py)
 - [eiger_9m.py](./eiger_9m.py)
 With the current implementation, the detector initialization should be done by a beamline scientist through the JungfrauJoch WEB UI by choosing the 
 appropriate detector (1.5M or 9M) before loading the device config with BEC. BEC will check upon connecting if the selected detector matches the expected one.
 A preview stream for images is also provided which is forwarded and accessible through the `preview_image` signal.
 For more specific details, please check the code documentation. 
--- a/csaxs_bec/devices/jungfraujoch/eiger.py
+++ b/csaxs_bec/devices/jungfraujoch/eiger.py
@@ -1,34 +1,23 @@
 """
 Generic integration of JungfrauJoch backend with Eiger detectors
 for the cSAXS beamline at the Swiss Light Source.
-The WEB UI is available on http://sls-jfjoch-001:8080
+Integration module for Eiger detectors at the cSAXS beamline with JungfrauJoch backend.
-NOTE: this may not be the best place to store this information. It should be migrated to
+A few notes on setup and operation of the Eiger detectors through the JungfrauJoch broker:
 beamline documentation for debugging of Eiger & JungfrauJoch.
 The JungfrauJoch server for cSAXS runs on sls-jfjoch-001.psi.ch
 User with sufficient rights may use:
 - sudo systemctl restart jfjoch_broker
 - sudo systemctl status jfjoch_broker
 to check and/or restart the broker for the JungfrauJoch server.
 Some extra notes for setting up the detector:
 - If the energy on JFJ is set via DetectorSettings, the variable in DatasetSettings will be ignored
 - Changes in energy may take time,  good to implement logic that only resets energy if needed.
 - For the Eiger, the frame_time_us in DetectorSettings is ignored, only the frame_time_us in
  the DatasetSettings is relevant
 - The bit_depth will be adjusted automatically based on the exp_time. Here, we need to ensure
-  that subsequent triggers properly
+  that subsequent triggers properly consider the readout_time of the boards. For the Eiger detectors
-  consider the readout_time of the boards. For Jungfrau detectors, the difference between
+  at cSAXS, a readout time of 20us is configured through the JungfrauJoch deployment config. This
-  count_time_us and frame_time_us is the readout_time of the boards. For the Eiger, this needs
+  setting is sufficiently large for the detectors if they run in parallel mode.
  to be taken into account during the integration.
 - beam_center and detector settings are required input arguments, thus, they may be set to wrong
  values for acquisitions to start. Please keep this in mind.
 Hardware related notes:
 - If there is an HW issue with the detector, power cycling may help.
- The sls_detector package is available on console on /sls/X12SA/data/gac-x12sa/erik/micromamba
+- The sls_detector package is available on console on /sls/x12sa/applications/erik/micromamba
    - Run: source setup_9m.sh # Be careful, this connects to the detector, so it should not be
      used during operation
    - Useful commands:
@@ -39,9 +28,6 @@ Hardware related notes:
        - cd power_control_user/
        - ./on
        - ./off
 Further information that may be relevant for debugging:
 JungfrauJoch - one needs to connect to the jfj-server (sls-jfjoch-001)
 """
 from __future__ import annotations
@@ -84,10 +70,19 @@ class EigerError(Exception):
 class Eiger(PSIDeviceBase):
    """
-    Base integration of the Eiger1.5M and Eiger9M at cSAXS. All relevant
+    Base integration of the Eiger1.5M and Eiger9M at cSAXS.
    Args:
        name (str) : Name of the device
        detector_name (str): Name of the detector. Supports ["EIGER 9M", "EIGER 8.5M (tmp)", "EIGER 1.5M"]
        host (str): Hostname of the Jungfrau Joch server.
        port (int): Port of the Jungfrau Joch server.
        scan_info (ScanInfo): The scan info to use.
        device_manager (DeviceManagerDS): The device manager to use.
        **kwargs: Additional keyword arguments.
    """
-    USER_ACCESS = ["detector_distance", "beam_center"]
+    USER_ACCESS = ["set_detector_distance", "set_beam_center"]
    file_event = Cpt(FileEventSignal, name="file_event")
    preview_image = Cpt(PreviewSignal, name="preview_image", ndim=2)
@@ -105,23 +100,12 @@ class Eiger(PSIDeviceBase):
        device_manager=None,
        **kwargs,
    ):
        """
        Initialize the PSI Device Base class.
        Args:
            name (str) : Name of the device
            detector_name (str): Name of the detector. Supports ["EIGER 9M", "EIGER 8.5M (tmp)", "EIGER 1.5M"]
            host (str): Hostname of the Jungfrau Joch server.
            port (int): Port of the Jungfrau Joch server.
            scan_info (ScanInfo): The scan info to use.
            device_manager (DeviceManagerDS): The device manager to use.
            **kwargs: Additional keyword arguments.
        """
        super().__init__(name=name, scan_info=scan_info, device_manager=device_manager, **kwargs)
        self._host = f"{host}:{port}"
        self.jfj_client = JungfrauJochClient(host=self._host, parent=self)
        # NOTE: fetch this information from JungfrauJochClient during on_connected!
        self.jfj_preview_client = JungfrauJochPreview(
-            url="tcp://129.129.95.114:5400", cb=self.preview_image.put
+            url="tcp://129.129.95.114:5400", cb=self._preview_callback
        )  # IP of sls-jfjoch-001.psi.ch on port 5400 for ZMQ stream
        self.device_manager = device_manager
        self.detector_name = detector_name
@@ -129,53 +113,102 @@ class Eiger(PSIDeviceBase):
        self._beam_center = beam_center
        self._readout_time = readout_time
        self._full_path = ""
        self._num_triggers = 0
        self._wait_for_on_complete = 20  # seconds
        if self.device_manager is not None:
            self.device_manager: DeviceManagerDS
    def _preview_callback(self, message: dict) -> None:
        """
        Callback method for handling preview messages as received from the JungfrauJoch preview stream.
        These messages are dictionary dumps as described in the JFJ ZMQ preview stream documentation.
        (https://jungfraujoch.readthedocs.io/en/latest/ZEROMQ_STREAM.html#preview-stream).
        Args:
            message (dict): The message received from the preview stream.
        """
        if message.get("type", "") == "image":
            data = message.get("data", {}).get("default", None)
            if data is None:
                logger.error(f"Received image message on device {self.name} without data.")
                return
            logger.info(f"Received preview image on device {self.name}")
            self.preview_image.put(data)
    # pylint: disable=missing-function-docstring
    @property
    def detector_distance(self) -> float:
        """The detector distance in mm."""
        return self._detector_distance
    @detector_distance.setter
    def detector_distance(self, value: float) -> None:
        """Set the detector distance in mm."""
        if value <= 0:
            raise ValueError("Detector distance must be a positive value.")
        self._detector_distance = value
    def set_detector_distance(self, distance: float) -> None:
        """
        Set the detector distance in mm.
        Args:
            distance (float): The detector distance in mm.
        """
        self.detector_distance = distance
    # pylint: disable=missing-function-docstring
    @property
    def beam_center(self) -> tuple[float, float]:
        """The beam center in pixels. (x,y)"""
        return self._beam_center
    @beam_center.setter
    def beam_center(self, value: tuple[float, float]) -> None:
-        """Set the beam center in pixels. (x,y)"""
+        if any(coord < 0 for coord in value):
            raise ValueError("Beam center coordinates must be non-negative.")
        self._beam_center = value
-    def on_init(self) -> None:
+    def set_beam_center(self, x: float, y: float) -> None:
        """
-        Called when the device is initialized.
+        Set the beam center coordinates in pixels.
-        No siganls are connected at this point,
+        Args:
-        thus should not be set here but in on_connected instead.
+            x (float): The x coordinate of the beam center in pixels.
            y (float): The y coordinate of the beam center in pixels.
        """
        self.beam_center = (x, y)
    def on_init(self) -> None:
        """Hook called during device initialization."""
    # pylint: disable=arguments-differ
    def wait_for_connection(self, timeout: float = 10) -> None:
        """
        Wait for the device to be connected to the JungfrauJoch backend.
        Args:
            timeout (float): Timeout in seconds to wait for the connection.
        """
        self.jfj_client.api.status_get(_request_timeout=timeout)  # If connected, this responds
    def on_connected(self) -> None:
        """
        Hook called after the device is connected to through the device server.
        Called after the device is connected and its signals are connected.
-        Default values for signals should be set here.
+        Default values for signals should be set here. Currently, the detector needs to be
        initialised manually through the WEB UI of JungfrauJoch. Once agreed upon, the automated
        initialisation can be re-enabled here (code commented below).
        """
        start_time = time.time()
        logger.debug(f"On connected called for {self.name}")
        self.jfj_client.stop(request_timeout=3)
        # Check which detector is selected
        # Get available detectors
        available_detectors = self.jfj_client.api.config_select_detector_get(_request_timeout=5)
        logger.debug(f"Available detectors {available_detectors}")
        # Get current detector
        current_detector_name = ""
-        if available_detectors.current_id:
+        if available_detectors.current_id is not None:
            detector_selection = [
                det.description
                for det in available_detectors.detectors
@@ -190,8 +223,9 @@ class Eiger(PSIDeviceBase):
            raise RuntimeError(
                f"Detector {self.detector_name} is not in IDLE state, current state: {self.jfj_client.detector_state}. Please initialize the detector in the WEB UI: {self._host}."
            )
-        # TODO - check again once Eiger should be initialized automatically, currently human initialization is expected
+
-        # # Once the automation should be enabled, we may use here
+        # TODO - Currently the initialisation of the detector is done manually through the WEB UI. Once adjusted
        # this can be automated here again.
        # detector_selection = [
        #     det for det in available_detectors.detectors if det.id == self.detector_name
        # ]
@@ -207,41 +241,51 @@ class Eiger(PSIDeviceBase):
        # Setup Detector settings, here we may also set the energy already as this might be time consuming
        settings = DetectorSettings(frame_time_us=int(500), timing=DetectorTiming.TRIGGER)
-        self.jfj_client.set_detector_settings(settings, timeout=10)
+        self.jfj_client.set_detector_settings(settings, timeout=5)
        # Set the file writer to the appropriate output for the HDF5 file
        file_writer_settings = FileWriterSettings(overwrite=True, format=FileWriterFormat.NXMXVDS)
        logger.debug(
            f"Setting writer_settings: {yaml.dump(file_writer_settings.to_dict(), indent=4)}"
        )
        # Setup the file writer settings
        self.jfj_client.api.config_file_writer_put(
            file_writer_settings=file_writer_settings, _request_timeout=10
        )
        # Start the preview client
        self.jfj_preview_client.connect()
        self.jfj_preview_client.start()
-        logger.info(f"Connected to JungfrauJoch preview stream at {self.jfj_preview_client.url}")
+        logger.info(
            f"Device {self.name} initialized after {time.time()-start_time:.2f}s. Preview stream connected on url: {self.jfj_preview_client.url}"
        )
    def on_stage(self) -> DeviceStatus | None:
        """
-        Called while staging the device.
+        Hook called when staging the device. Information about the upcoming scan can be accessed from the scan_info object.
-
+        scan_msg = self.scan_info.msg
        Information about the upcoming scan can be accessed from the scan_info object.
        """
        start_time = time.time()
        scan_msg = self.scan_info.msg
-        # Set acquisition parameter
+
-        # TODO add check of mono energy, this can then also be passed to DatasetSettings
+        # TODO: Check mono energy from device in BEC
        # Setting incident energy in keV
        incident_energy = 12.0
        # Setting up exp_time and num_triggers acquisition parameter
        exp_time = scan_msg.scan_parameters.get("exp_time", 0)
-        if exp_time <= self._readout_time:
+        if exp_time <= self._readout_time:  # Exp_time must be at least the readout time
            raise ValueError(
-                f"Receive scan request for scan {scan_msg.scan_name} with exp_time {exp_time}s, which must be larger than the readout time {self._readout_time}s of the detector {self.detector_name}."
+                f"Value error on device {self.name}: Exposure time {exp_time}s is less than readout time {self._readout_time}s."
            )
-        frame_time_us = exp_time  #
+        self._num_triggers = int(
-        ntrigger = int(scan_msg.num_points * scan_msg.scan_parameters["frames_per_trigger"])
+            scan_msg.num_points * scan_msg.scan_parameters["frames_per_trigger"]
-        # Fetch file path
+        )
        # Setting up the full path for file writing
        self._full_path = get_full_path(scan_msg, name=f"{self.name}_master")
        self._full_path = os.path.abspath(os.path.expanduser(self._full_path))
        # Inform BEC about upcoming file event
        self.file_event.put(
            file_path=self._full_path,
@@ -249,11 +293,14 @@ class Eiger(PSIDeviceBase):
            successful=False,
            hinted_h5_entries={"data": "entry/data/data"},
        )
        # JFJ adds _master.h5 automatically
        path = os.path.relpath(self._full_path, start="/sls/x12sa/data").removesuffix("_master.h5")
        # Create dataset settings for API call.
        data_settings = DatasetSettings(
-            image_time_us=int(frame_time_us * 1e6),  # This is currently ignored
+            image_time_us=int(exp_time * 1e6),
-            ntrigger=ntrigger,
+            ntrigger=self._num_triggers,
            file_prefix=path,
            beam_x_pxl=int(self._beam_center[0]),
            beam_y_pxl=int(self._beam_center[1]),
@@ -261,11 +308,15 @@ class Eiger(PSIDeviceBase):
            incident_energy_ke_v=incident_energy,
        )
        logger.debug(f"Setting data_settings: {yaml.dump(data_settings.to_dict(), indent=4)}")
-        prep_time = start_time - time.time()
+        prep_time = time.time()
-        logger.debug(f"Prepared information for eiger to start acquisition in {prep_time:.2f}s")
+        self.jfj_client.wait_for_idle(timeout=10)  # Ensure we are in IDLE state
        self.jfj_client.wait_for_idle(timeout=10, request_timeout=10)  # Ensure we are in IDLE state
        self.jfj_client.start(settings=data_settings)  # Takes around ~0.6s
-        logger.debug(f"Wait for IDLE and start call took {time.time()-start_time-prep_time:.2f}s")
+
        # Time the stage process
        logger.info(
            f"Device {self.name} staged for scan. Time spent {time.time()-start_time:.2f}s,"
            f" with {time.time()-prep_time:.2f}s spent with communication to JungfrauJoch."
        )
    def on_unstage(self) -> DeviceStatus:
        """Called while unstaging the device."""
@@ -278,7 +329,9 @@ class Eiger(PSIDeviceBase):
    def _file_event_callback(self, status: DeviceStatus) -> None:
        """Callback to update the file_event signal when the acquisition is done."""
-        logger.info(f"Acquisition done callback called for {self.name} for status {status.success}")
+        logger.debug(
            f"File event callback on complete status for device {self.name}: done={status.done}, successful={status.success}"
        )
        self.file_event.put(
            file_path=self._full_path,
            done=status.done,
@@ -287,19 +340,44 @@ class Eiger(PSIDeviceBase):
        )
    def on_complete(self) -> DeviceStatus:
-        """Called to inquire if a device has completed a scans."""
+        """
        Called at the end of the scan. The method should implement an asynchronous wait for the
        device to complete the acquisition. A callback to update the file_event signal is
        attached that resolves the file event when the acquisition is done.
        Returns:
            DeviceStatus: The status object representing the completion of the acquisition.
        """
        def wait_for_complete():
            start_time = time.time()
-            timeout = 10
+            # NOTE: This adjust the time (s) that should be waited for completion of the scan.
-            for _ in range(timeout):
+            timeout = self._wait_for_on_complete
-                if self.jfj_client.wait_for_idle(timeout=1, request_timeout=10):
+            while time.time() - start_time < timeout:
                if self.jfj_client.wait_for_idle(timeout=1, raise_on_timeout=False):
                    # TODO: Once available, add check for
                    statistics: MeasurementStatistics = (
                        self.jfj_client.api.statistics_data_collection_get(_request_timeout=5)
                    )
                    if statistics.images_collected < self._num_triggers:
                        raise EigerError(
                            f"Device {self.name} acquisition incomplete. "
                            f"Expected {self._num_triggers} triggers, "
                            f"but only {statistics.images_collected} were collected."
                        )
                    return
                logger.info(
                    f"Waiting for device {self.name} to finish complete, time elapsed: "
                    f"{time.time() - start_time}."
                )
            statistics: MeasurementStatistics = self.jfj_client.api.statistics_data_collection_get(
                _request_timeout=5
            )
            broker_status = self.jfj_client.jfj_status
            raise TimeoutError(
-                f"Timeout after waiting for detector {self.name} to complete for {time.time()-start_time:.2f}s, measurement statistics: {yaml.dump(statistics.to_dict(), indent=4)}"
+                f"Timeout after waiting for device {self.name} to complete for {time.time()-start_time:.2f}s \n \n"
                f"Broker status: \n{yaml.dump(broker_status.to_dict(), indent=4)} \n \n"
                f"Measurement statistics: \n{yaml.dump(statistics.to_dict(), indent=4)}"
            )
        status = self.task_handler.submit_task(wait_for_complete, run=True)
@@ -312,7 +390,11 @@ class Eiger(PSIDeviceBase):
    def on_stop(self) -> None:
        """Called when the device is stopped."""
-        self.jfj_client.stop(
+        self.jfj_client.stop(request_timeout=0.5)
            request_timeout=0.5
        )  # Call should not block more than 0.5 seconds to stop all devices...
        self.task_handler.shutdown()
    def on_destroy(self):
        """Called when the device is destroyed."""
        self.jfj_preview_client.stop()
        self.on_stop()
        return super().on_destroy()
--- a/csaxs_bec/devices/jungfraujoch/eiger_9m.py
+++ b/csaxs_bec/devices/jungfraujoch/eiger_9m.py
@@ -21,18 +21,18 @@ if TYPE_CHECKING:  # pragma no cover
    from bec_server.device_server.device_server import DeviceManagerDS
 EIGER9M_READOUT_TIME_US = 500e-6  # 500 microseconds in s
-DETECTOR_NAME = "EIGER 8.5M (tmp)"  # "EIGER 9M""
+DETECTOR_NAME = "EIGER 9M"  # "EIGER 9M""
 # pylint:disable=invalid-name
 class Eiger9M(Eiger):
    """
-    Eiger 1.5M specific integration for the in-vaccum Eiger.
+    EIGER 9M specific integration for the in-vaccum Eiger.
    The logic implemented here is coupled to the DelayGenerator integration,
    repsonsible for the global triggering of all devices through a single Trigger logic.
    Please check the eiger.py class for more details about the integration of relevant backend
-    services. The detector_name must be set to "EIGER 1.5M:
+    services. The detector_name must be set to "EIGER 9M":
    """
    USER_ACCESS = Eiger.USER_ACCESS + []  # Add more user_access methods here.
--- a/csaxs_bec/devices/jungfraujoch/jungfrau_joch_client.py
+++ b/csaxs_bec/devices/jungfraujoch/jungfrau_joch_client.py
@@ -1,13 +1,15 @@
-"""Module with client interface for the Jungfrau Joch detector API"""
+"""Module with a thin client wrapper around the Jungfrau Joch detector API"""
 from __future__ import annotations
 import enum
 import threading
 import time
 import traceback
 from typing import TYPE_CHECKING
 import requests
 import yaml
 from bec_lib.logger import bec_logger
 from jfjoch_client.api.default_api import DefaultApi
 from jfjoch_client.api_client import ApiClient
@@ -18,7 +20,7 @@ from jfjoch_client.models.detector_settings import DetectorSettings
 logger = bec_logger.logger
-if TYPE_CHECKING:
+if TYPE_CHECKING:  # pragma: no cover
    from ophyd import Device
@@ -29,7 +31,10 @@ class JungfrauJochClientError(Exception):
 class DetectorState(str, enum.Enum):
-    """Possible Detector states for Jungfrau Joch detector"""
+    """
    Enum states of the BrokerStatus state. The pydantic model validates in runtime,
    thus we keep the possible states here for a convenient overview and access.
    """
    INACTIVE = "Inactive"
    IDLE = "Idle"
@@ -40,13 +45,15 @@ class DetectorState(str, enum.Enum):
 class JungfrauJochClient:
-    """Thin wrapper around the Jungfrau Joch API client.
+    """
    Jungfrau Joch API client wrapper. It provides a thin wrapper methods around the API client,
    that allow to connect, initialise, wait for state changes, set settings, start and stop
    acquisitions.
-    sudo systemctl restart jfjoch_broker
+    Args:
-    sudo systemctl status jfjoch_broker
+        host (str): Hostname of the Jungfrau Joch broker service.
-
+                    Default is "http://sls-jfjoch-001:8080"
-    It looks as if the detector is not being stopped properly.
+        parent (Device, optional): Parent ophyd device, used for logging purposes.
    One module remains running, how can we restart the detector?
    """
    def __init__(
@@ -59,50 +66,63 @@ class JungfrauJochClient:
        self._parent_name = parent.name if parent else self.__class__.__name__
    @property
-    def jjf_state(self) -> BrokerStatus:
+    def jfj_status(self) -> BrokerStatus:
-        """Get the status of JungfrauJoch"""
+        """Broker status of JungfrauJoch."""
        response = self.api.status_get()
        return BrokerStatus(**response.to_dict())
    # pylint: disable=missing-function-docstring
    @property
    def initialised(self) -> bool:
        """Check if jfj is connected and ready to receive commands"""
        return self._initialised
    @initialised.setter
    def initialised(self, value: bool) -> None:
        """Set the connected status"""
        self._initialised = value
-    # TODO this is not correct, as it may be that the state in INACTIVE. Models are not in sync...
+    # pylint: disable=missing-function-docstring
    # REMOVE all model enums as most of the validation takes place in the Pydantic models, i.e. BrokerStatus here..
    @property
    def detector_state(self) -> DetectorState:
-        """Get the status of JungfrauJoch"""
+        return DetectorState(self.jfj_status.state)
        return DetectorState(self.jjf_state.state)
-    def connect_and_initialise(self, timeout: int = 10, **kwargs) -> None:
+    def connect_and_initialise(self, timeout: int = 10) -> None:
-        """Check if JungfrauJoch is connected and ready to receive commands"""
+        """
        Connect and initialise the JungfrauJoch detector. The detector must be in
        IDLE state to become initialised. This is a blocking call, the timeout parameter
        will be passed to the HTTP requests timeout method of the wait_for_idle method.
        Args:
            timeout (int): Timeout in seconds for the initialisation and waiting for IDLE state.
        """
        status = self.detector_state
        # TODO: #135 Check if the detector has to be in INACTIVE state before initialisation
        if status != DetectorState.IDLE:
-            self.api.initialize_post()  # This is a blocking call....
+            self.api.initialize_post()
-            self.wait_for_idle(timeout, request_timeout=timeout)  # Blocking call
+            self.wait_for_idle(timeout)
        self.initialised = True
    def set_detector_settings(self, settings: dict | DetectorSettings, timeout: int = 10) -> None:
-        """Set the detector settings. JungfrauJoch must be in IDLE, Error or Inactive state.
+        """
-        Note, the full settings have to be provided, otherwise the settings will be overwritten with default values.
+        Set the detector settings. The state of JungfrauJoch must be in IDLE,
        Error or Inactive state. Please note: a full set of setttings has to be provided,
        otherwise the settings will be overwritten with default values.
        Args:
            settings (dict): dictionary of settings
            timeout (int): Timeout in seconds for the HTTP request to set the settings.
        """
        state = self.detector_state
        if state not in [DetectorState.IDLE, DetectorState.ERROR, DetectorState.INACTIVE]:
            logger.info(
                f"JungfrauJoch backend fo device {self._parent_name} is not in IDLE state,"
                " waiting 1s before retrying..."
            )
            time.sleep(1)  # Give the detector 1s to become IDLE, retry
            state = self.detector_state
            if state not in [DetectorState.IDLE, DetectorState.ERROR, DetectorState.INACTIVE]:
                raise JungfrauJochClientError(
-                    f"Error in {self._parent_name}. Detector must be in IDLE, ERROR or INACTIVE state to set settings. Current state: {state}"
+                    f"Error on {self._parent_name}. Detector must be in IDLE, ERROR or INACTIVE"
                    " state to set settings. Current state: {state}"
                )
        if isinstance(settings, dict):
@@ -110,28 +130,36 @@ class JungfrauJochClient:
        try:
            self.api.config_detector_put(detector_settings=settings, _request_timeout=timeout)
        except requests.exceptions.Timeout:
-            raise TimeoutError(f"Timeout while setting detector settings for {self._parent_name}")
+            raise TimeoutError(
                f"Timeout on device {self._parent_name} while setting detector settings:\n "
                f"{yaml.dump(settings, indent=4)}."
            )
        except Exception:
            content = traceback.format_exc()
            logger.error(
                f"Error on device {self._parent_name} while setting detector settings:\n "
                f"{yaml.dump(settings, indent=4)}. Error traceback: {content}"
            )
            raise JungfrauJochClientError(
-                f"Error while setting detector settings for {self._parent_name}: {content}"
+                f"Error on device {self._parent_name} while setting detector settings:\n "
                f"{yaml.dump(settings, indent=4)}. Full traceback: {content}."
            )
    def start(self, settings: dict | DatasetSettings, request_timeout: float = 10) -> None:
-        """Start the mesaurement. DatasetSettings must be provided, and JungfrauJoch must be in IDLE state.
+        """
-        The method call is blocking and JungfrauJoch will be ready to measure after the call resolves.
+        Start the acquisition with the provided dataset settings.
        The detector must be in IDLE state. Settings must always provide a full set of
        parameters, missing parameters will be set to default values.
        Args:
-            settings (dict): dictionary of settings
+            settings (dict | DatasetSettings): Dataset settings to start the acquisition with.
-
+            request_timeout (float): Timeout in sec for the HTTP request to start the acquisition.
        Please check the DataSettings class for the available settings. Minimum required settings are
        beam_x_pxl, beam_y_pxl, detector_distance_mm, incident_energy_keV.
        """
        state = self.detector_state
        if state != DetectorState.IDLE:
            raise JungfrauJochClientError(
-                f"Error in {self._parent_name}. Detector must be in IDLE state to set settings. Current state: {state}"
+                f"Error on device {self._parent_name}. "
                f"Detector must be in IDLE state to start acquisition. Current state: {state}"
            )
        if isinstance(settings, dict):
@@ -141,46 +169,80 @@ class JungfrauJochClient:
                dataset_settings=settings, _request_timeout=request_timeout
            )
        except requests.exceptions.Timeout:
            content = traceback.format_exc()
            logger.error(
                f"Timeout error after {request_timeout} seconds on device {self._parent_name} "
                f"during 'start' call with dataset settings: {yaml.dump(settings, indent=4)}. \n"
                f"Traceback: {content}"
            )
            raise TimeoutError(
-                f"TimeoutError in JungfrauJochClient for parent device {self._parent_name} for 'start' call"
+                f"Timeout error after {request_timeout} seconds on device {self._parent_name} "
                f"during 'start' call with dataset settings: {yaml.dump(settings, indent=4)}."
            )
        except Exception:
            content = traceback.format_exc()
            logger.error(
                f"Error on device {self._parent_name} during 'start' post with dataset settings: \n"
                f"{yaml.dump(settings, indent=4)}. \nTraceback: {content}"
            )
            raise JungfrauJochClientError(
-                f"Error in JungfrauJochClient for parent device {self._parent_name} during 'start' call: {content}"
+                f"Error on device {self._parent_name} during 'start' post with dataset settings: \n"
                f"{yaml.dump(settings, indent=4)}. \nTraceback: {content}."
            )
    def stop(self, request_timeout: float = 0.5) -> None:
        """Stop the acquisition, this only logs errors and is not raising."""
        try:
            self.api.cancel_post_with_http_info(_request_timeout=request_timeout)
        except requests.exceptions.Timeout:
            content = traceback.format_exc()
            logger.error(
                f"Timeout in JungFrauJochClient for device {self._parent_name} during stop: {content}"
            )
        except Exception:
            content = traceback.format_exc()
            logger.error(
                f"Error in JungFrauJochClient for device {self._parent_name} during stop: {content}"
            )
-    def wait_for_idle(self, timeout: int = 10, request_timeout: float | None = None) -> bool:
+        def _stop_call(self):
-        """Wait for JungfrauJoch to be in Idle state. Blocking call with timeout.
+            try:
                self.api.cancel_post_with_http_info()  # (_request_timeout=request_timeout)
            except requests.exceptions.Timeout:
                content = traceback.format_exc()
                logger.error(
                    f"Timeout error after {request_timeout} seconds on device {self._parent_name} "
                    f"during stop: {content}"
                )
            except Exception:
                content = traceback.format_exc()
                logger.error(f"Error on device {self._parent_name} during stop: {content}")
        thread = threading.Thread(
            target=_stop_call, daemon=True, args=(self,), name="stop_jungfraujoch_thread"
        )
        thread.start()
    def wait_for_idle(self, timeout: int = 10, raise_on_timeout: bool = True) -> bool:
        """
        Method to wait until the detector is in IDLE state. This is a blocking call with a
        timeout that can be specified. The additional parameter raise_on_timeout can be used to
        raise an exception on timeout instead of returning boolean True/False.
        Args:
            timeout (int): timeout in seconds
            raise_on_timeout (bool): If True, raises an exception on timeout. Default is True.
        Returns:
            bool: True if the detector is in IDLE state, False if timeout occurred
        """
        if request_timeout is None:
            request_timeout = timeout
        try:
-            self.api.wait_till_done_post(timeout=timeout, _request_timeout=request_timeout)
+            self.api.wait_till_done_post(timeout=timeout, _request_timeout=timeout)
        except requests.exceptions.Timeout:
            raise TimeoutError(f"HTTP request timeout in wait_for_idle for {self._parent_name}")
        except Exception:
            content = traceback.format_exc()
-            logger.debug(f"Waiting for device {self._parent_name} to become IDLE: {content}")
+            logger.info(
                f"Timeout after {timeout} seconds on device {self._parent_name} in wait_for_idle: {content}"
            )
            if raise_on_timeout:
                raise TimeoutError(
                    f"Timeout after {timeout} seconds on device {self._parent_name} in wait_for_idle."
                )
            return False
        except Exception as exc:
            content = traceback.format_exc()
            logger.info(
                f"Error on device {self._parent_name} in wait_for_idle. Full traceback: {content}"
            )
            if raise_on_timeout:
                raise JungfrauJochClientError(
                    f"Error on device {self._parent_name} in wait_for_idle: {content}"
                ) from exc
            return False
        return True
--- a/csaxs_bec/devices/jungfraujoch/jungfraujoch_preview.py
+++ b/csaxs_bec/devices/jungfraujoch/jungfraujoch_preview.py
@@ -1,22 +1,136 @@
-"""Module for the Eiger preview ZMQ stream."""
+"""
 Module for the JungfrauJoch preview ZMQ stream for the Eiger detector at cSAXS.
 The Preview client is implemented for the JungfrauJoch ZMQ PUB-SUB interface, and
 should be independent of the EIGER detector type.
 The client connects to the ZMQ PUB-SUB preview stream and calls a user provided callback
 function with the decompressed messages received from the stream. The callback needs to be
 able to deal with the different message types sent by the JungfrauJoch server ("start",
 "image", "end") as described in the JungfrauJoch ZEROMQ preview stream documentation.
 (https://jungfraujoch.readthedocs.io/en/latest/ZEROMQ_STREAM.html#preview-stream).
 """
 from __future__ import annotations
 import json
 import threading
 import time
 from typing import Callable
 import cbor2
 import numpy as np
 import zmq
 from bec_lib.logger import bec_logger
 from dectris.compression import decompress
 logger = bec_logger.logger
-ZMQ_TOPIC_FILTER = b""
+###############################
 ###### CBOR TAG DECODERS ######
 ###############################
 # Dectris specific CBOR tags and decoders for Jungfrau data
 # Reference:
 # https://github.com/dectris/documentation/blob/main/stream_v2/examples/client.py
 def decode_multi_dim_array(tag: cbor2.CBORTag, column_major: bool = False):
    """Decode a multi-dimensional array from a CBOR tag."""
    dimensions, contents = tag.value
    if isinstance(contents, list):
        array = np.empty((len(contents),), dtype=object)
        array[:] = contents
    elif isinstance(contents, (np.ndarray, np.generic)):
        array = contents
    else:
        raise cbor2.CBORDecodeValueError("expected array or typed array")
    return array.reshape(dimensions, order="F" if column_major else "C")
 def decode_typed_array(tag: cbor2.CBORTag, dtype: str):
    """Decode a typed array from a CBOR tag."""
    if not isinstance(tag.value, bytes):
        raise cbor2.CBORDecodeValueError("expected byte string in typed array")
    return np.frombuffer(tag.value, dtype=dtype)
 def decode_dectris_compression(tag: cbor2.CBORTag):
    """Decode a Dectris compressed array from a CBOR tag."""
    algorithm, elem_size, encoded = tag.value
    return decompress(encoded, algorithm, elem_size=elem_size)
 #########################################
 #### Dectris CBOR TAG Extensions ########
 #########################################
 # Mapping of various additional CBOR tags from Dectris to decoder functions
 tag_decoders = {
    40: lambda tag: decode_multi_dim_array(tag, column_major=False),
    64: lambda tag: decode_typed_array(tag, dtype="u1"),
    65: lambda tag: decode_typed_array(tag, dtype=">u2"),
    66: lambda tag: decode_typed_array(tag, dtype=">u4"),
    67: lambda tag: decode_typed_array(tag, dtype=">u8"),
    68: lambda tag: decode_typed_array(tag, dtype="u1"),
    69: lambda tag: decode_typed_array(tag, dtype="<u2"),
    70: lambda tag: decode_typed_array(tag, dtype="<u4"),
    71: lambda tag: decode_typed_array(tag, dtype="<u8"),
    72: lambda tag: decode_typed_array(tag, dtype="i1"),
    73: lambda tag: decode_typed_array(tag, dtype=">i2"),
    74: lambda tag: decode_typed_array(tag, dtype=">i4"),
    75: lambda tag: decode_typed_array(tag, dtype=">i8"),
    77: lambda tag: decode_typed_array(tag, dtype="<i2"),
    78: lambda tag: decode_typed_array(tag, dtype="<i4"),
    79: lambda tag: decode_typed_array(tag, dtype="<i8"),
    80: lambda tag: decode_typed_array(tag, dtype=">f2"),
    81: lambda tag: decode_typed_array(tag, dtype=">f4"),
    82: lambda tag: decode_typed_array(tag, dtype=">f8"),
    83: lambda tag: decode_typed_array(tag, dtype=">f16"),
    84: lambda tag: decode_typed_array(tag, dtype="<f2"),
    85: lambda tag: decode_typed_array(tag, dtype="<f4"),
    86: lambda tag: decode_typed_array(tag, dtype="<f8"),
    87: lambda tag: decode_typed_array(tag, dtype="<f16"),
    1040: lambda tag: decode_multi_dim_array(tag, column_major=True),
    56500: lambda tag: decode_dectris_compression(tag),  # pylint: disable=unnecessary-lambda
 }
 def tag_hook(decoder, tag: int):
    """
    Tag hook for the cbor2.loads method. Both arguments "decoder" and "tag" mus be present.
    We use the tag to choose the respective decoder from the tag_decoders registry if available.
    """
    tag_decoder = tag_decoders.get(tag.tag)
    return tag_decoder(tag) if tag_decoder else tag
 ######################
 #### ZMQ Settings ####
 ######################
 ZMQ_TOPIC_FILTER = b""  # Subscribe to all topics
 ZMQ_CONFLATE_SETTING = 1  # Keep only the most recent message
 ZMQ_RCVHWM_SETTING = 1  # Set high water mark to 1, this configures the max number of queue messages
 #################################
 #### Jungfrau Preview Client ####
 #################################
 class JungfrauJochPreview:
    """
    Preview client for the JungfrauJoch ZMQ preview stream. The client is started with
    a URL to receive the data from the JungfrauJoch PUB-SUB preview interface, and a
    callback function that is called with messages received from the preview stream.
    The callback needs to be able to deal with the different message types sent
    by the JungfrauJoch server ("start", "image", "end") as described in the
    JungfrauJoch ZEROMQ preview stream documentation. Messages are dictionary dumps.
    (https://jungfraujoch.readthedocs.io/en/latest/ZEROMQ_STREAM.html#preview-stream).
    Args:
        url (str): ZMQ PUB-SUB preview stream URL.
        cb (Callable): Callback function called with messages received from the stream.
    """
    USER_ACCESS = ["start", "stop"]
    def __init__(self, url: str, cb: Callable):
@@ -27,16 +141,18 @@ class JungfrauJochPreview:
        self._on_update_callback = cb
    def connect(self):
-        """Connect to the JungfrauJoch PUB-SUB streaming interface
+        """
-
+        Connect to the JungfrauJoch PUB-SUB streaming interface. If the connection is refused
-        JungfrauJoch may reject connection for a few seconds when it restarts,
+        it will reattempt a second time after a one second delay.
        so if it fails, wait a bit and try to connect again.
        """
        # pylint: disable=no-member
        context = zmq.Context()
        self._socket = context.socket(zmq.SUB)
        self._socket.setsockopt(zmq.CONFLATE, ZMQ_CONFLATE_SETTING)
        self._socket.setsockopt(zmq.SUBSCRIBE, ZMQ_TOPIC_FILTER)
        self._socket.setsockopt(zmq.RCVHWM, ZMQ_RCVHWM_SETTING)
        try:
            self._socket.connect(self.url)
        except ConnectionRefusedError:
@@ -44,17 +160,26 @@ class JungfrauJochPreview:
            self._socket.connect(self.url)
    def start(self):
        """Start the ZMQ update loop in a background thread."""
        self._zmq_thread = threading.Thread(
            target=self._zmq_update_loop, daemon=True, name="JungfrauJoch_live_preview"
        )
        self._zmq_thread.start()
    def stop(self):
        """Stop the ZMQ update loop and wait for the thread to finish."""
        self._shutdown_event.set()
        if self._zmq_thread:
-            self._zmq_thread.join()
+            self._zmq_thread.join(timeout=1.0)
-    def _zmq_update_loop(self):
+    def _zmq_update_loop(self, poll_interval: float = 0.2):
        """
        ZMQ update loop running in a background thread. The polling is throttled by
        the poll_interval parameter.
        Args:
            poll_interval (float): Time in seconds to wait between polling attempts.
        """
        while not self._shutdown_event.is_set():
            if self._socket is None:
                self.connect()
@@ -64,18 +189,21 @@ class JungfrauJochPreview:
                # Happens when ZMQ partially delivers the multipart message
                pass
            except zmq.error.Again:
-                # Happens when receive queue is empty
+                logger.debug(
-                time.sleep(0.1)
+                    f"ZMQ Again exception, receive queue is empty for JFJ preview at {self.url}."
                )
            finally:
                # We throttle the polling to avoid heavy load on the device server
                time.sleep(poll_interval)
    def _poll(self):
        """
-        Poll the ZMQ socket for new data. It will throttle the data update and
+        Poll the ZMQ socket for new data. We are currently subscribing and unsubscribing
-        only subscribe to the topic for a single update. This is not very nice
+        for each poll loop to avoid receiving too many messages. Throttling of the update
-        but it seems like there is currently no option to set the update rate on
+        loop is handled in the _zmq_update_loop method.
        the backend.
        """
-        if self._shutdown_event.wait(0.2):
+        if self._shutdown_event.is_set():
            return
        try:
@@ -90,7 +218,19 @@ class JungfrauJochPreview:
            # Unsubscribe from the topic
            self._socket.setsockopt(zmq.UNSUBSCRIBE, ZMQ_TOPIC_FILTER)
-    def _parse_data(self, data):
+    def _parse_data(self, bytes_list: list[bytes]):
-        # TODO decode and parse the data
+        """
-        # self._on_update_callback(data)
+        Parse the received ZMQ data from the JungfrauJoch preview stream.
-        pass
+        We will call the _on_update_callback with the decompressed messages as a dictionary.
        The callback needs to be able to deal with the different message types sent
        by the JungfrauJoch server ("start", "image", "end") as described in the
        JungfrauJoch ZEROMQ preview stream documentation. Messages are dictionary dumps.
        (https://jungfraujoch.readthedocs.io/en/latest/ZEROMQ_STREAM.html#preview-stream).
        Args:
            bytes_list (list[bytes]): List of byte messages received from ZMQ recv_multipart.
        """
        for byte_msg in bytes_list:
            msg = cbor2.loads(byte_msg, tag_hook=tag_hook)
            self._on_update_callback(msg)
--- a/csaxs_bec/devices/omny/rt/rt_flomni_ophyd.py
+++ b/csaxs_bec/devices/omny/rt/rt_flomni_ophyd.py
@@ -498,6 +498,9 @@ class RtFlomniController(Controller):
        )
        # while scan is running
        while mode > 0:
            #TODO here?: scan abortion if no progress in scan *raise error
            # logger.info(f"Current scan position {current_position_in_scan} out of {number_of_positions_planned}")
            mode, number_of_positions_planned, current_position_in_scan = self.get_scan_status()
            time.sleep(0.01)
@@ -629,6 +632,8 @@ class RtFlomniMotor(Device, PositionerBase):
    SUB_CONNECTION_CHANGE = "connection_change"
    _default_sub = SUB_READBACK
    connectionTimeout = 20
    def __init__(
        self,
        axis_Id,
--- a/csaxs_bec/devices/omny/shutter.py
+++ b/csaxs_bec/devices/omny/shutter.py
@@ -1,82 +1,87 @@
-import time
+"""
-import socket
+Fast Shutter control for OMNY setup. If started with a config file in which the device_manager
 has a 'fsh' device (cSAXSFastEpicsShutter), this device will be used as the shutter.
 Otherwise, the device will create a dummy shutter device that will log warnings when shutter
 methods are called, but will not raise exceptions.
 """
 from bec_lib.logger import bec_logger
 from ophyd import Component as Cpt
-from ophyd import Device
+from ophyd import Device, Signal
-from ophyd import EpicsSignal
+from ophyd_devices import PSIDeviceBase
 logger = bec_logger.logger
-class OMNYFastEpicsShutterError(Exception):
+class OMNYFastShutter(PSIDeviceBase, Device):
    pass
 def _detect_host_pv():
    """Detect host subnet and return appropriate PV name."""
    try:
        hostname = socket.gethostname()
        local_ip = socket.gethostbyname(hostname)
        if local_ip.startswith("129.129.122."):
            return "X12SA-ES1-TTL:OUT_01"
        else:
            return "XOMNYI-XEYE-DUMMYSHUTTER:0"
    except Exception as ex:
        print(f"Warning: could not detect IP subnet ({ex}), using dummy shutter.")
        return "XOMNYI-XEYE-DUMMYSHUTTER:0"
 class OMNYFastEpicsShutter(Device):
    """
-    Fast EPICS shutter with automatic PV selection based on host subnet.
+    Fast Shutter control for OMNY setup. If started with at the beamline, it will expose
    the shutter control methods (fshopen, fshclose, fshstatus, fshinfo) from the
    cSAXSFastEpicsShutter device. The device is identified by the 'fsh' name in the device manager.
    If the 'fsh' device is not found in the device manager, this device will create a dummy shutter
    and log warnings when shutter methods are called, but will not raise exceptions.
    """
-    USER_ACCESS = ["fshopen", "fshclose", "fshstatus", "fshinfo", "help"]
+    USER_ACCESS = ["fshopen", "fshclose", "fshstatus", "fshinfo", "help", "fshstatus_readback"]
    SUB_VALUE = "value"
    _default_sub = SUB_VALUE
-    # PV is detected dynamically at import time
+    shutter = Cpt(Signal, name="shutter")
    shutter = Cpt(EpicsSignal, name="shutter", read_pv=_detect_host_pv(), auto_monitor=True)
    def __init__(self, prefix="", *, name, **kwargs):
        super().__init__(prefix, name=name, **kwargs)
        self.shutter.subscribe(self._emit_value)
    def _emit_value(self, **kwargs):
        timestamp = kwargs.pop("timestamp", time.time())
        self.wait_for_connection()
        self._run_subs(sub_type=self.SUB_VALUE, timestamp=timestamp, obj=self)
    # -----------------------------------------------------
    # User-facing shutter control functions
    # -----------------------------------------------------
    # pylint: disable=invalid-name
    def _check_if_cSAXS_shutter_exists_in_config(self) -> bool:
        """
        Check on the device manager if the shutter device exists.
        Returns:
            bool: True if the 'fsh' device exists in the device manager, False otherwise
        """
        if self.device_manager.devices.get("fsh", None) is None:
            logger.warning(f"Fast shutter device not found for {self.name}.")
            return False
        return True
    def fshopen(self):
        """Open the fast shutter."""
-        try:
+        if self._check_if_cSAXS_shutter_exists_in_config():
-            self.shutter.put(1, wait=True)
+            return self.device_manager.devices["fsh"].fshopen()
-        except Exception as ex:
+        else:
-            raise OMNYFastEpicsShutterError(f"Failed to open shutter: {ex}")
+            self.shutter.put(1)
    def fshclose(self):
        """Close the fast shutter."""
-        try:
+        if self._check_if_cSAXS_shutter_exists_in_config():
-            self.shutter.put(0, wait=True)
+            return self.device_manager.devices["fsh"].fshclose()
-        except Exception as ex:
+        else:
-            raise OMNYFastEpicsShutterError(f"Failed to close shutter: {ex}")
+            self.shutter.put(0)
    def fshstatus(self):
        """Return the fast shutter status (0=closed, 1=open)."""
-        try:
+        if self._check_if_cSAXS_shutter_exists_in_config():
            return self.device_manager.devices["fsh"].fshstatus()
        else:
            return self.shutter.get()
        except Exception as ex:
            raise OMNYFastEpicsShutterError(f"Failed to read shutter status: {ex}")
    def fshinfo(self):
        """Print information about which EPICS PV channel is being used."""
-        pvname = self.shutter.pvname
+        if self._check_if_cSAXS_shutter_exists_in_config():
-        print(f"Fast shutter connected to EPICS channel: {pvname}")
+            return self.device_manager.devices["fsh"].fshinfo()
-        return pvname
+        else:
            print("Using dummy fast shutter device. No EPICS channel is connected.")
    def help(self):
        """Display available user methods."""
        print("Available methods:")
        for method in self.USER_ACCESS:
            print(f"  - {method}")
    def fshstatus_readback(self):
        """Return the fast shutter status (0=closed, 1=open) from the readback signal."""
        if self._check_if_cSAXS_shutter_exists_in_config():
            return self.device_manager.devices["fsh"].fshstatus_readback()
        else:
            self.shutter.get()
--- a/csaxs_bec/scans/flomni_fermat_scan.py
+++ b/csaxs_bec/scans/flomni_fermat_scan.py
@@ -27,6 +27,7 @@ from bec_lib import bec_logger, messages
 from bec_lib.endpoints import MessageEndpoints
 from bec_server.scan_server.errors import ScanAbortion
 from bec_server.scan_server.scans import SyncFlyScanBase
 from csaxs_bec.devices.epics.delay_generator_csaxs.delay_generator_csaxs import TRIGGERSOURCE
 logger = bec_logger.logger
@@ -73,14 +74,13 @@ class FlomniFermatScan(SyncFlyScanBase):
            >>> scans.flomni_fermat_scan(fovx=20, fovy=25, cenx=0.02, ceny=0, zshift=0, angle=0, step=0.5, exp_time=0.01)
        """
-        super().__init__(parameter=parameter, **kwargs)
+        super().__init__(parameter=parameter, exp_time=exp_time, **kwargs)
        self.show_live_table = False
        self.axis = []
        self.fovx = fovx
        self.fovy = fovy
        self.cenx = cenx
        self.ceny = ceny
        self.exp_time = exp_time
        self.step = step
        self.zshift = zshift
        self.angle = angle
@@ -151,6 +151,9 @@ class FlomniFermatScan(SyncFlyScanBase):
        yield from self.stubs.send_rpc_and_wait("rty", "set", self.positions[0][1])
    def _prepare_setup_part2(self):
        # Prepare DDG1 to use 
        yield from self.stubs.send_rpc_and_wait("ddg1", "set_trigger", TRIGGERSOURCE.EXT_RISING_EDGE.value)
        if self.flomni_rotation_status:
            self.flomni_rotation_status.wait()
@@ -307,6 +310,10 @@ class FlomniFermatScan(SyncFlyScanBase):
        logger.warning("No positions found to return to start")
    def cleanup(self):
        yield from self.stubs.send_rpc_and_wait("ddg1", "set_trigger", TRIGGERSOURCE.SINGLE_SHOT.value)
        yield from super().cleanup()
    def run(self):
        self.initialize()
        yield from self.read_scan_motors()
--- a/pyproject.toml
+++ b/pyproject.toml
@@ -25,6 +25,8 @@ dependencies = [
    "bec_widgets",
    "zmq",
    "opencv-python",
    "dectris-compression", # for JFJ preview stream decompression
    "cbor2",
 ]
 [project.optional-dependencies]
--- a/tests/conftest.py
+++ b/tests/conftest.py
@@ -0,0 +1,14 @@
 """
 Conftest runs for all tests in this directory and subdirectories. Thereby, we know for
 certain that the SocketSignal.READBACK_TIMEOUT is set to 0 for all tests, which prevents
 hanging tests when a readback is attempted on a non-connected socket.
 """
 # conftest.py
 import pytest
 from ophyd_devices.utils.socket import SocketSignal
@pytest.fixture(autouse=True)
 def patch_socket_timeout(monkeypatch):
    monkeypatch.setattr(SocketSignal, "READBACK_TIMEOUT", 0.0)
--- a/tests/tests_devices/test_delay_generator_csaxs.py
+++ b/tests/tests_devices/test_delay_generator_csaxs.py
@@ -282,10 +282,11 @@ def test_ddg1_stage(mock_ddg1: DDG1):
    mock_ddg1.scan_info.msg.scan_parameters["exp_time"] = exp_time
    mock_ddg1.scan_info.msg.scan_parameters["frames_per_trigger"] = frames_per_trigger
    mock_ddg1.fast_shutter_control._read_pv.mock_data = 0  # Simulate shutter control
    mock_ddg1.stage()
-    shutter_width = 2e-3 + exp_time * frames_per_trigger + 1e-3
+    shutter_width = mock_ddg1._shutter_to_open_delay + exp_time * frames_per_trigger
    assert np.isclose(mock_ddg1.burst_mode.get(), 1)  # burst mode is enabled
    assert np.isclose(mock_ddg1.burst_delay.get(), 0)
@@ -302,6 +303,25 @@ def test_ddg1_stage(mock_ddg1: DDG1):
    assert np.isclose(mock_ddg1.ef.width.get(), 1e-6)
    assert mock_ddg1.staged == ophyd.Staged.yes
    mock_ddg1.unstage()
    # Test if shutter is kept open..
    mock_ddg1.fast_shutter_control._read_pv.mock_data = 1  # Simulate shutter control is kept open
    # Test method
    mock_ddg1.keep_shutter_open_during_scan(True)
    shutter_width = mock_ddg1._shutter_to_open_delay + exp_time * frames_per_trigger
    assert np.isclose(
        shutter_width, exp_time * frames_per_trigger
    )  # Shutter to open delay is not added as shutter is kept open
    # Simulate fly scan, so no extra trigger for MCS card.
    mock_ddg1.scan_info.msg.scan_type = "fly"
    mock_ddg1.stage()
    # Shutter channel cd
    assert np.isclose(mock_ddg1.cd.delay.get(), 0)
    assert np.isclose(mock_ddg1.cd.width.get(), shutter_width)
    # MCS channel ef or gate
    assert np.isclose(mock_ddg1.ef.delay.get(), 0)
    assert np.isclose(mock_ddg1.ef.width.get(), 0)  # No triggering of MCS due to shutter fly scan
 def test_ddg1_on_trigger(mock_ddg1: DDG1):
@@ -331,9 +351,28 @@ def test_ddg1_on_trigger(mock_ddg1: DDG1):
    #################################
    with mock.patch.object(ddg, "_prepare_mcs_on_trigger") as mock_prepare_mcs:
        mock_prepare_mcs.return_value = ophyd.StatusBase(done=True, success=True)
        # MCS card is present and enabled, should call prepare_mcs_on_trigger
        # and the status should resolve once acuiring goes from 1 to 0.
        status = ddg.trigger()
        assert status.done is False
        mcs = ddg.device_manager.devices.get("mcs", None)
        assert mcs is not None
        mcs.acquiring._read_pv.mock_data = 1  # Simulate acquiring started
        assert status.done is False
        mcs.acquiring._read_pv.mock_data = 0  # Simulate acquiring stopped
        status.wait(timeout=1)  # Wait for the status to be done
        assert status.done is True
        assert status.success is True
        mock_prepare_mcs.assert_called_once()
        # Now we disable the mcs card, and trigger again. This should not call prepare_mcs_on_trigger
        # and should fallback to polling the DDG for END_OF_BURST status bit.
        # Disable mcs card
        mcs.enabled = False
        status = ddg.trigger()
        # Check that the poll thread run event is set
        # Careful in debugger, there is a timeout based on the exp_time + 5s default
        assert ddg._poll_thread_run_event.is_set()
        assert not ddg._poll_thread_poll_loop_done.is_set()
--- a/tests/tests_devices/test_eiger.py
+++ b/tests/tests_devices/test_eiger.py
@@ -5,6 +5,7 @@ from time import time
 from typing import TYPE_CHECKING, Generator
 from unittest import mock
 import numpy as np
 import pytest
 from bec_lib.messages import FileMessage, ScanStatusMessage
 from jfjoch_client.models.broker_status import BrokerStatus
@@ -78,7 +79,7 @@ def detector_list(request) -> Generator[DetectorList, None, None]:
            ),
            DetectorListElement(
                id=2,
-                description="EIGER 8.5M (tmp)",
+                description="EIGER 9M",
                serial_number="123456",
                base_ipv4_addr="192.168.0.1",
                udp_interface_count=1,
@@ -103,7 +104,11 @@ def eiger_1_5m(mock_scan_info) -> Generator[Eiger1_5M, None, None]:
    name = "eiger_1_5m"
    dev = Eiger1_5M(name=name, beam_center=(256, 256), detector_distance=100.0)
    dev.scan_info.msg = mock_scan_info
-    yield dev
+    try:
        yield dev
    finally:
        if dev._destroyed is False:
            dev.destroy()
@pytest.fixture(scope="function")
@@ -113,7 +118,19 @@ def eiger_9m(mock_scan_info) -> Generator[Eiger9M, None, None]:
    name = "eiger_9m"
    dev = Eiger9M(name=name)
    dev.scan_info.msg = mock_scan_info
-    yield dev
+    try:
        yield dev
    finally:
        if dev._destroyed is False:
            dev.destroy()
 def test_eiger_wait_for_connection(eiger_1_5m, eiger_9m):
    """Test the wait_for_connection metho is calling status_get on the JFJ API client."""
    for eiger in (eiger_1_5m, eiger_9m):
        with mock.patch.object(eiger.jfj_client.api, "status_get") as mock_status_get:
            eiger.wait_for_connection(timeout=1)
            mock_status_get.assert_called_once_with(_request_timeout=1)
@pytest.mark.parametrize("detector_state", ["Idle", "Inactive"])
@@ -141,7 +158,7 @@ def test_eiger_1_5m_on_connected(eiger_1_5m, detector_list, detector_state):
        else:
            eiger.on_connected()
            assert mock_set_det.call_args == mock.call(
-                DetectorSettings(frame_time_us=500, timing=DetectorTiming.TRIGGER), timeout=10
+                DetectorSettings(frame_time_us=500, timing=DetectorTiming.TRIGGER), timeout=5
            )
            assert mock_file_writer.call_args == mock.call(
                file_writer_settings=FileWriterSettings(
@@ -179,7 +196,7 @@ def test_eiger_9m_on_connected(eiger_9m, detector_list, detector_state):
        else:
            eiger.on_connected()
            assert mock_set_det.call_args == mock.call(
-                DetectorSettings(frame_time_us=500, timing=DetectorTiming.TRIGGER), timeout=10
+                DetectorSettings(frame_time_us=500, timing=DetectorTiming.TRIGGER), timeout=5
            )
            assert mock_file_writer.call_args == mock.call(
                file_writer_settings=FileWriterSettings(
@@ -216,11 +233,39 @@ def test_eiger_on_stop(eiger_1_5m):
        stop_event.wait(timeout=5)  # Thread should be killed from task_handler
 def test_eiger_on_destroy(eiger_1_5m):
    """Test the on_destroy logic of the Eiger detector. This is equivalent for 9M and 1_5M."""
    eiger = eiger_1_5m
    start_event = threading.Event()
    stop_event = threading.Event()
    def tmp_task():
        start_event.set()
        try:
            while True:
                time.sleep(0.1)
        finally:
            stop_event.set()
    eiger.task_handler.submit_task(tmp_task)
    start_event.wait(timeout=5)
    with (
        mock.patch.object(eiger.jfj_preview_client, "stop") as mock_jfj_preview_client_stop,
        mock.patch.object(eiger.jfj_client, "stop") as mock_jfj_client_stop,
    ):
        eiger.on_destroy()
        mock_jfj_preview_client_stop.assert_called_once()
        mock_jfj_client_stop.assert_called_once()
        stop_event.wait(timeout=5)
@pytest.mark.timeout(25)
@pytest.mark.parametrize("raise_timeout", [True, False])
 def test_eiger_on_complete(eiger_1_5m, raise_timeout):
    """Test the on_complete logic of the Eiger detector. This is equivalent for 9M and 1_5M."""
    eiger = eiger_1_5m
    eiger._wait_for_on_complete = 1  # reduce wait time for testing
    callback_completed_event = threading.Event()
@@ -230,7 +275,7 @@ def test_eiger_on_complete(eiger_1_5m, raise_timeout):
    unblock_wait_for_idle = threading.Event()
-    def mock_wait_for_idle(timeout: int, request_timeout: float):
+    def mock_wait_for_idle(timeout: float, raise_on_timeout: bool) -> bool:
        if unblock_wait_for_idle.wait(timeout):
            if raise_timeout:
                return False
@@ -238,11 +283,18 @@ def test_eiger_on_complete(eiger_1_5m, raise_timeout):
        return False
    with (
        mock.patch.object(
            eiger.jfj_client.api, "status_get", return_value=BrokerStatus(state="Idle")
        ),
        mock.patch.object(eiger.jfj_client, "wait_for_idle", side_effect=mock_wait_for_idle),
        mock.patch.object(
            eiger.jfj_client.api,
            "statistics_data_collection_get",
-            return_value=MeasurementStatistics(run_number=1),
+            return_value=MeasurementStatistics(
                run_number=1,
                images_collected=eiger.scan_info.msg.num_points
                * eiger.scan_info.msg.scan_parameters["frames_per_trigger"],
            ),
        ),
    ):
        status = eiger.complete()
@@ -284,7 +336,7 @@ def test_eiger_file_event_callback(eiger_1_5m, tmp_path):
    assert file_msg.hinted_h5_entries == {"data": "entry/data/data"}
-def test_eiger_on_sage(eiger_1_5m):
+def test_eiger_on_stage(eiger_1_5m):
    """Test the on_stage and on_unstage logic of the Eiger detector. This is equivalent for 9M and 1_5M."""
    eiger = eiger_1_5m
    scan_msg = eiger.scan_info.msg
@@ -316,3 +368,35 @@ def test_eiger_on_sage(eiger_1_5m):
        )
        assert mock_start.call_args == mock.call(settings=data_settings)
        assert eiger.staged is Staged.yes
 def test_eiger_set_det_distance_test_beam_center(eiger_1_5m):
    """Test the set_detector_distance and set_beam_center methods. Equivalent for 9M and 1_5M."""
    eiger = eiger_1_5m
    old_distance = eiger.detector_distance
    new_distance = old_distance + 100
    old_beam_center = eiger.beam_center
    new_beam_center = (old_beam_center[0] + 20, old_beam_center[1] + 50)
    eiger.set_detector_distance(new_distance)
    assert eiger.detector_distance == new_distance
    eiger.set_beam_center(x=new_beam_center[0], y=new_beam_center[1])
    assert eiger.beam_center == new_beam_center
    with pytest.raises(ValueError):
        eiger.set_beam_center(x=-10, y=100)  # Cannot set negative beam center
    with pytest.raises(ValueError):
        eiger.detector_distance = -50  # Cannot set negative detector distance
 def test_eiger_preview_callback(eiger_1_5m):
    """Preview callback test for the Eiger detector. This is equivalent for 9M and 1_5M."""
    eiger = eiger_1_5m
    # NOTE: I don't find models for the CBOR messages used by JFJ, currently using a dummay dict.
    # Please adjust once the proper model is found.
    for msg_type in ["start", "end", "image", "calibration", "metadata"]:
        msg = {"type": msg_type, "data": {"default": np.array([[1, 2], [3, 4]])}}
        with mock.patch.object(eiger.preview_image, "put") as mock_preview_put:
            eiger._preview_callback(msg)
            if msg_type == "image":
                mock_preview_put.assert_called_once_with(msg["data"]["default"])
            else:
                mock_preview_put.assert_not_called()
--- a/tests/tests_devices/test_epics_devices.py
+++ b/tests/tests_devices/test_epics_devices.py
@@ -0,0 +1,37 @@
 """Module to test epics devices."""
 import pytest
 from ophyd_devices.tests.utils import patched_device
 from csaxs_bec.devices.epics.fast_shutter import cSAXSFastEpicsShutter
@pytest.fixture
 def fast_shutter_device():
    """Fixture to create a patched cSAXSFastEpicsShutter device for testing."""
    with patched_device(cSAXSFastEpicsShutter, name="fsh", prefix="X12SA-ES1-TTL:") as device:
        yield device
 def test_fast_shutter_methods(fast_shutter_device):
    """Test the user-facing methods of the cSAXSFastEpicsShutter device."""
    assert fast_shutter_device.name == "fsh", "Device name should be 'fsh'"
    assert fast_shutter_device.prefix == "X12SA-ES1-TTL:", "Device prefix is 'X12SA-ES1-TTL:'"
    # Test fshopen and fshclose
    fast_shutter_device.fshopen()
    assert fast_shutter_device.shutter.get() == 1, "Shutter should be open (1) after fshopen()"
    assert fast_shutter_device.fshstatus() == 1, "fshstatus should return 1 when shutter is open"
    fast_shutter_device.fshclose()
    assert fast_shutter_device.shutter.get() == 0, "Shutter should be closed (0) after fshclose()"
    assert fast_shutter_device.fshstatus() == 0, "fshstatus should return 0 when shutter is closed"
    # shutter_readback is connected to separate PV.
    fast_shutter_device.shutter_readback._read_pv.mock_data = 1  # Simulate readback showing open
    assert (
        fast_shutter_device.fshstatus_readback() == 1
    ), "fshstatus_readback should return 1 when shutter readback shows open"
    fast_shutter_device.shutter_readback._read_pv.mock_data = 0  # Simulate readback showing closed
    assert (
        fast_shutter_device.fshstatus_readback() == 0
    ), "fshstatus_readback should return 0 when shutter readback shows closed"
--- a/tests/tests_devices/test_eps.py
+++ b/tests/tests_devices/test_eps.py
@@ -0,0 +1,99 @@
 # pylint: skip-file
 from __future__ import annotations
 import pytest
 from ophyd_devices.tests.utils import patched_device
 from csaxs_bec.devices.epics.eps import EPS
 ALL_PVS = [
    # ALARMS
    "X12SA-EPS-PLC:AlarmCnt_EPS",
    "ARS00-MIS-PLC-01:AlarmCnt_Frontends",
    # FRONTEND VALVES
    "X12SA-FE-VVPG-0000:PLC_OPEN",
    "X12SA-FE-VVPG-1010:PLC_OPEN",
    "X12SA-FE-VVFV-2010:PLC_OPEN",
    "X12SA-FE-VVPG-2010:PLC_OPEN",
    # Optics VALVES
    "X12SA-OP-VVPG-1010:PLC_OPEN",
    "X12SA-OP-VVPG-2010:PLC_OPEN",
    "X12SA-OP-VVPG-3010:PLC_OPEN",
    "X12SA-OP-VVPG-3020:PLC_OPEN",
    "X12SA-OP-VVPG-4010:PLC_OPEN",
    "X12SA-OP-VVPG-5010:PLC_OPEN",
    "X12SA-OP-VVPG-6010:PLC_OPEN",
    "X12SA-OP-VVPG-7010:PLC_OPEN",
    # Endstation VALVES
    "X12SA-ES-VVPG-1010:PLC_OPEN",
    # Frontend SHUTTERS
    "X12SA-FE-PSH1-EMLS-0010:OPEN",
    "X12SA-FE-STO1-EMLS-0010:OPEN",
    # Optics SHUTTERS
    "X12SA-OP-PSH1-EMLS-7010:OPEN",
    # DMM Monochromator
    "X12SA-OP-DMM-ETTC-3010:TEMP",
    "X12SA-OP-DMM-ETTC-3020:TEMP",
    "X12SA-OP-DMM-ETTC-3030:TEMP",
    "X12SA-OP-DMM-ETTC-3040:TEMP",
    "X12SA-OP-DMM-EMLS-3010:THRU",
    "X12SA-OP-DMM-EMLS-3020:IN",
    "X12SA-OP-DMM-EMLS-3030:THRU",
    "X12SA-OP-DMM-EMLS-3040:IN",
    "X12SA-OP-DMM-EMSW-3050:SWITCH",
    "X12SA-OP-DMM-EMSW-3060:SWITCH",
    "X12SA-OP-DMM-EMSW-3070:SWITCH",
    "X12SA-OP-DMM1:ENERGY-GET",
    "X12SA-OP-DMM1:POSITION",
    "X12SA-OP-DMM1:STRIPE",
    # CCM Monochromator
    "X12SA-OP-CCM-ETTC-4010:TEMP",
    "X12SA-OP-CCM-ETTC-4020:TEMP",
    "X12SA-OP-CCM-EMSW-4010:SWITCH",
    "X12SA-OP-CCM-EMSW-4020:SWITCH",
    "X12SA-OP-CCM-EMSW-4030:SWITCH",
    "X12SA-OP-CCM1:ENERGY-GET",
    "X12SA-OP-CCM1:POSITION",
    # Water Cooling
    "X12SA-OP-SL1-EFSW-2010:FLOW",
    "X12SA-OP-SL2-EFSW-2010:FLOW",
    "X12SA-OP-EB1-EFSW-5010:FLOW",
    "X12SA-OP-EB1-EFSW-5020:FLOW",
    "X12SA-OP-SL3-EFSW-5010:FLOW",
    "X12SA-OP-KB-EFSW-6010:FLOW",
    "X12SA-OP-PSH1-EFSW-7010:FLOW",
    "X12SA-ES-EB2-EFSW-1010:FLOW",
    "X12SA-OP-CS-ECVW-0010:PLC_OPEN",
    "X12SA-OP-CS-ECVW-0020:PLC_OPEN",
    # Request PVs
    "X12SA-EPS-PLC:ACKERR-REQUEST",
    "X12SA-OP-CS-ECVW:PLC_REQUEST",
 ]
@pytest.fixture
 def eps():
    dev_name = "EPS"
    with patched_device(EPS, name=dev_name) as eps:
        yield eps
 def test_eps_has_signals(eps):
    """Test that all expected PVs are present in the eps device."""
    found_pvs = [walk.item._read_pv.pvname for walk in eps.walk_signals()]
    assert set(found_pvs) == set(
        ALL_PVS
    ), f"Expected PVs {ALL_PVS} but found {set(ALL_PVS) - set(found_pvs)}"
 # pylint: disable=line-too-long
 expected_show_all_output = "\x1b[1mX12SA EPS status\x1b[0m\n\n\x1b[1mEPS Alarms\x1b[0m\n  - X12SA EPS Alarm count            0\n  - FrontEnd MIS Alarm count         0\n\n\x1b[1mValves Frontend\x1b[0m\n  - FE-VVPG-0000                     \x1b[91mCLOSED\x1b[0m\n  - FE-VVPG-1010                     \x1b[91mCLOSED\x1b[0m\n  - FE-VVFV-2010                     \x1b[91mCLOSED\x1b[0m\n  - FE-VVPG-2010                     \x1b[91mCLOSED\x1b[0m\n\n\x1b[1mValves Optics Hutch\x1b[0m\n  - OP-VVPG-1010                     \x1b[91mCLOSED\x1b[0m\n  - OP-VVPG-2010                     \x1b[91mCLOSED\x1b[0m\n  - OP-VVPG-3010                     \x1b[91mCLOSED\x1b[0m\n  - OP-VVPG-3020                     \x1b[91mCLOSED\x1b[0m\n  - OP-VVPG-4010                     \x1b[91mCLOSED\x1b[0m\n  - OP-VVPG-5010                     \x1b[91mCLOSED\x1b[0m\n  - OP-VVPG-6010                     \x1b[91mCLOSED\x1b[0m\n  - OP-VVPG-7010                     \x1b[91mCLOSED\x1b[0m\n\n\x1b[1mValves ES Hutch\x1b[0m\n  - ES-VVPG-1010                     \x1b[91mCLOSED\x1b[0m\n\n\x1b[1mShutters Frontend\x1b[0m\n  - FE-PSH1-EMLS-0010                \x1b[91mCLOSED\x1b[0m\n  - FE-STO1-EMLS-0010                \x1b[91mCLOSED\x1b[0m\n\n\x1b[1mShutters Endstation\x1b[0m\n  - OP-PSH1-EMLS-7010                \x1b[91mCLOSED\x1b[0m\n\n\x1b[1mDMM Monochromator\x1b[0m\n  - DMM Temp Surface 1               0.0\n  - DMM Temp Surface 2               0.0\n  - DMM Temp Shield 1 (disaster)     0.0\n  - DMM Temp Shield 2 (disaster)     0.0\n  - DMM Translation ThruPos          \x1b[91mINACTIVE\x1b[0m\n  - DMM Translation InPos            \x1b[91mINACTIVE\x1b[0m\n  - DMM Bragg ThruPos                \x1b[91mINACTIVE\x1b[0m\n  - DMM Bragg InPos                  \x1b[91mINACTIVE\x1b[0m\n  - DMM Heater Fault XTAL 1          \x1b[92mOK\x1b[0m\n  - DMM Heater Fault XTAL 2          \x1b[92mOK\x1b[0m\n  - DMM Heater Fault Support 1       \x1b[92mOK\x1b[0m\n  - DMM Energy                       0.0000\n  - DMM Position                     out of beam\n  - DMM Stripe                       Stripe 1 W/B4C\n\n\x1b[1mCCM Monochromator\x1b[0m\n  - CCM Temp Crystal                 0.0\n  - CCM Temp Shield (disaster)       0.0\n  - CCM Heater Fault 1               \x1b[92mOK\x1b[0m\n  - CCM Heater Fault 2               \x1b[92mOK\x1b[0m\n  - CCM Heater Fault 3               \x1b[92mOK\x1b[0m\n  - CCM Energy                       0.0000\n  - CCM Position                     out of beam\n\n\x1b[1mCooling Water\x1b[0m\n  - OP-SL1-EFSW-2010                 \x1b[91mFAIL\x1b[0m\n  - OP-SL2-EFSW-2010                 \x1b[91mFAIL\x1b[0m\n  - OP-EB1-EFSW-5010                 \x1b[91mFAIL\x1b[0m\n  - OP-EB1-EFSW-5020                 \x1b[91mFAIL\x1b[0m\n  - OP-SL3-EFSW-5010                 \x1b[91mFAIL\x1b[0m\n  - OP-KB-EFSW-6010                  \x1b[91mFAIL\x1b[0m\n  - OP-PSH1-EFSW-7010                \x1b[91mFAIL\x1b[0m\n  - ES-EB2-EFSW-1010                 \x1b[91mFAIL\x1b[0m\n  - OP-CS-ECVW-0010                  \x1b[91mCLOSED\x1b[0m\n  - OP-CS-ECVW-0020                  \x1b[91mCLOSED\x1b[0m\n\n\x1b[96mHint:\x1b[0m Both water cooling valves are CLOSED.\nYou can open them using: \x1b[1mdev.x12saEPS.water_cooling_op()\x1b[0m\n"
 def test_eps_show_all(eps, capsys):
    """Test that the show_all method outputs the expected status."""
    eps.show_all()
    output = capsys.readouterr().out
    assert (
        output == expected_show_all_output
    ), f"Expected output does not match actual output.\nExpected:\n{expected_show_all_output}\nActual:\n{output}"
Author	SHA1	Message	Date
appel_c	9db56f5273	refactor: Eiger refactoring, fix test and add docs. All checks were successful CI for csaxs_bec / test (pull_request) Successful in 1m34s Details CI for csaxs_bec / test (push) Successful in 1m33s Details	2026-02-16 14:13:55 +01:00
appel_c	705df4b253	fix: cleanup of eiger integration	2026-02-16 14:13:55 +01:00
appel_c	181b57494b	fix: Cleanup of jungfrau_joch_client	2026-02-16 14:13:55 +01:00
appel_c	efd51462fc	refactor(jungfraujoch-preview): Improve Jungfraujoch Preview module	2026-02-16 14:13:55 +01:00
appel_c	8a69c7aa36	fix(config): add eiger 9m to bl_detectors	2026-02-16 14:13:55 +01:00
appel_c	b19bfb7ca4	fix: improve integration with feedback from the beamline	2026-02-16 14:13:55 +01:00
appel_c	b818181da2	fix(mcs): wrap _progress_update callback in try except.	2026-02-16 14:13:55 +01:00
appel_c	303929f8e6	fix: Cleanup after tests at the beamline	2026-02-16 14:13:55 +01:00
appel_c	9f5799385c	fix(eiger): add dectris-decompression and dependencies.	2026-02-16 14:13:55 +01:00
x12sa	cb968abe73	minor changes from the beamline	2026-02-16 14:13:55 +01:00
x12sa	5ab763ad38	test at beamline All checks were successful CI for csaxs_bec / test (pull_request) Successful in 1m28s Details CI for csaxs_bec / test (push) Successful in 1m33s Details	2026-02-16 12:33:15 +01:00
appel_c	fa35ddf1a9	refactor(eps): deactivate black for eps.py to keep signal component formatted in single line.	2026-02-16 12:33:15 +01:00
appel_c	501bc52867	fix(eps): Fix tests and eps integration	2026-02-16 12:33:15 +01:00
appel_c	f35c51efa7	test(eps): Add tests for EPS device	2026-02-16 12:33:15 +01:00
appel_c	0c81c718d8	refactor(eps): Refactoring of EPS device from cSAXS	2026-02-16 12:33:15 +01:00
x12sa	ce88310125	fixed enable of water cooling	2026-02-16 12:33:15 +01:00
x12sa	e860571a64	water on method	2026-02-16 12:33:15 +01:00
x12sa	24bd5a71bc	added water cooling channels	2026-02-16 12:33:15 +01:00
x12sa	541eb97096	added "kind" to channel list	2026-02-16 12:33:15 +01:00
x12sa	7911717142	create class dynamically, monos added	2026-02-16 12:33:15 +01:00
x12sa	bdf94533a5	first version of csaxs eps	2026-02-16 12:33:15 +01:00
appel_c	5784331073	test(conftest): Add monkey patch for SocketSignal Readback_Timeout All checks were successful CI for csaxs_bec / test (push) Successful in 1m35s Details	2026-02-16 11:10:47 +01:00
x12sa	7a2c6629f7	refactor: add gh signal for ddg1 with TTL for full acquisition All checks were successful CI for csaxs_bec / test (pull_request) Successful in 1m31s Details CI for csaxs_bec / test (push) Successful in 1m33s Details	2026-02-16 10:18:37 +01:00
appel_c	75cc672f08	tests: fix tests for ddg1 All checks were successful CI for csaxs_bec / test (push) Successful in 1m32s Details CI for csaxs_bec / test (pull_request) Successful in 1m31s Details	2026-02-11 11:50:22 +01:00
appel_c	67ef20cfc8	fix(ddg): fix logic to resolve trigger on ddg1. Some checks failed CI for csaxs_bec / test (pull_request) Failing after 1m26s Details CI for csaxs_bec / test (push) Failing after 1m28s Details	2026-02-11 11:22:09 +01:00
appel_c	f8d2af4c5b	fix(ddg1): revert to shutter signal as mcs status signal is too slow Some checks failed CI for csaxs_bec / test (push) Failing after 1m27s Details CI for csaxs_bec / test (pull_request) Failing after 1m31s Details	2026-02-11 09:45:40 +01:00
appel_c	8195c12a35	fix(fast-shutter): Add close shutter on 'stop' call. Some checks failed CI for csaxs_bec / test (push) Failing after 1m25s Details CI for csaxs_bec / test (pull_request) Failing after 1m26s Details	2026-02-11 08:53:00 +01:00
appel_c	a45aa094ef	refactor(ddg1): Use mcs acquiring status to resolve trigger of DDG1	2026-02-11 08:52:38 +01:00
x12sa	2814add2de	fixes at beamline Some checks failed CI for csaxs_bec / test (push) Failing after 3m23s Details CI for csaxs_bec / test (pull_request) Failing after 3m25s Details	2026-02-10 10:59:18 +01:00
appel_c	32b4c39659	refactor(ddg): Add fsh signal to ddg, improve trigger logic. Some checks failed CI for csaxs_bec / test (push) Failing after 1m26s Details CI for csaxs_bec / test (pull_request) Failing after 1m27s Details	2026-02-09 14:11:00 +01:00
appel_c	8849b9ffea	fix(shutter); fix shutter_readback signal	2026-02-09 10:10:44 +01:00
appel_c	c3aa882b1d	fix(configs): add connectionTimeout=20s defaults to devices with SocketController Some checks failed CI for csaxs_bec / test (push) Failing after 1m28s Details CI for csaxs_bec / test (pull_request) Failing after 1m28s Details	2026-02-09 08:39:19 +01:00
appel_c	6fad4f2034	fix(fast-shutter): Fix cSAXS fast shutter device Some checks failed CI for csaxs_bec / test (push) Failing after 1m30s Details CI for csaxs_bec / test (pull_request) Failing after 1m30s Details	2026-02-09 08:29:08 +01:00
x12sa	ed8d012632	feat: add logic for ext/en in ddg, mcs and flomni Some checks failed CI for csaxs_bec / test (push) Failing after 1m24s Details CI for csaxs_bec / test (pull_request) Failing after 1m33s Details	2026-01-30 12:55:06 +01:00