1. Injector Diagnostics Status
LCLS DOE Review
October 25, 2006
Henrik Loos
Diagnostics overview
Beam profile monitors
Wire Scanners
Transverse Cavity
Toroids, BPMs, BLM see J. Frisch

2. LCLS Diagnostics Tasks
Charge
Toroids (Gun, Inj, BC, Und)
Faraday cups (Gun & Inj)
Trajectory & energy
Stripline BPMs (Gun, Inj, Linac)
Cavity BPMs (Und)
Profile monitors (Inj), compare position with alignment laser
Transverse emittance & energy spread
Wire scanners
YAG screen (Gun, Inj)
OTR screens (Inj, Linac)
Bunch length
Cherenkov radiators + streak camera (Gun)
Transverse cavity + OTR (Inj, Linac)
Coherent radiation power (BC)
Slice measurements
Horizontal emittance
T-cavity + quad + OTR
Vertical Emittance
OTR in dispersive beam line + quad
Energy spread
T-cavity + OTR in dispersive beam line

3. LCLS Injector Diagnostics
YAG, FC
YAG
Toroid
T-Cavity
Phase Monitor
Wire Scanner
Toroid
OTR
Toroid
OTR
YAG

4. Diagnostics Through BC1
RF Gun & Solenoid
L0a&L0b S-Band Linacs
T-Cav Sec 29
Transverse RF Cavity
Bunch-Compressor-1
(BPM, OTR, collimator)
OTR & Wire Scanners
Gun
Spectrometer
L1 S-Band Linac
Wire Scanners
+ OTR
135 MeV
250 MeV
TD-11
stopper
X-Band RF
Straight Ahead Spectrometer
Bunch Length Diagnostics
40 m

5. Requirements for YAG & OTR Monitors
Name
Location
Hor. Beam Size (mm)
Ver. Beam Size (mm)
Resol. (µm)
YAG01
GTL
1.400
[7.0]
[6.0] 15
YAG02
0.460
YAG03 L0
0.410
YAGG1
3.340
[45.0]
1.500
[8.0] 30
YAGS1
SAB
0.030
0.060
YAGS2
[10.0]
0.100
[12.0]
OTRH1
DL1
0.180
0.380 40
OTRH2
0.200
0.280
OTR1,3
0.125
0.130
OTR2
0.065
OTR4
0.160
[1.5]
0.120
[14.0] 25
OTRS1 7
Name
Location
Hor. Beam Size (mm)
Ver. Beam Size (mm)
Resol. (µm)
OTR11
BC1
3.800
0.100 30
OTR12
0.040
1.000 13
OTR21
BC2
2.600
0.050 16
OTRTCAV L3
0.070
[1.0]
OTR30
DL2
0.010
[0.2]
0.025 3
OTR33
OTRDMP
Dump
0.075
0.060
[0.6] 20
Large 50mm crystal required for gun spectrometer. Zoom lens needed.
Requires foil with and angle of 5 deg to the beam and a likewise tilted camera to keep the entire screen in focus.
Very high resolution required. Special optics design needs to be developed.

6. Beam Profile Monitor Specifications
YAG screens
High yield at low energy
108 Photons at 5pC
100µm to meet resolution
Saturation at high charge densities
Combined with Faraday cup in GTL -> camera shielding
Thin mirror (1mm) at higher energies
OTR screens
Small yield
Aluminum foil 1µm
Mitigates radiation issue
Foil damage is concern
Limited z-space
Foil at 45 degree
Depth of field ~1mm
Match reflection direction with TCAV or dispersion direction
OTR yield for 100mrad angular acceptance
Energy (MeV)
QE (%), nm
135
0.44
4300
0.98
13500
1.17

7. Optics Layout Used for all standard YAG/OTR screens Telecentric lens
Vacuum
Filters
Lens
CCD
OTR
e-beam
Reticule
YAG
Beam splitter
Illumination
Used for all standard YAG/OTR screens
Telecentric lens
55mm focal length
>100 line pairs/mm
Magnification up to 1:1
Stack of 2 insertable neutral density filters
Beam splitter and reticule for in situ calibration
Megapixel CCD with 12bit and 4.6µm pixel size
Radiation shielding in gun region

8. OTR/YAG Optics Design Actuator Optics Box CCD Screen Lens Filters Beam
Splitter
Reticle
Courtesy V. Srinivasan

9. OTR Profile Monitors

10. OTR Imager for Spectrometer
Need wide field of view in focus for measurements in spectrometer beam line
Tilt OTR screen and CCD by 5 degrees in 1:1 imaging
12um resolution tested
Device ready to install
B.X. Wang et al. PAC05

11. Simulation of OTR Beam Size Measurement
Simulation of CCD image
Include 0.5% TR yield, photon shot noise, and typical CCD parameters for quantum efficiency, read out noise, pixel size, digitizer gain
Calculation of beam size
Generate beam profile with 10σ bounding box
Compare rms width of profile with original Gaussian beam size
Simulation agrees well with OTR measurement at GTF
Error of 5% in beam size for beam of 0.1nC, 260µm at 10µm resolution
Q = 0.1nC
E = 135 MeV

12. YAG Efficiency Nφ = 14µm-1 l sin2(θ/2)
YAGG1 beam image at 5 pC
Nφ = 14µm-1 l sin2(θ/2)
l = 0.1mm, θ = 70mrad, Nφ = 1.7/e-
1nC: Nφ = 1*1010
200pC: Nφ = 2*109
5pC: Nφ = 5*107

13. CCD Camera and Lens Test
Uniq Vision CCD Dark Image Test
TECM55 lens with ruler (scale 1/64”)
Periodic BG structure removed with background subtraction
Resolution: B/W transition < 20um

14. Profile Monitor Controlsx
CCD Image
YAG Crystal
Rows y
Rate limit electron beam
Single bunch & burst mode
Prevent foil damage and limit camera irradiation
Camera control
Cameralink and EPICS IOC
Buffered
Screen
Image processing
Flip image to match image coordinates with beam
Background subtraction
Automated image cropping
Beam size calculation
Different algorithms
Gaussian fit
Baseline cut, etc.
Mock-up

15. Software Development

16. Profile Monitor Commissioning Tasks
Verify correct image polarity and calibration.
Compare with alignment laser, BPMs and wire scanners.
Find proper attenuation filter for YAG profile monitors.
Determine beam center with alignment laser.

17. Wire Scanner Status Requirements Hardware status Software status
Step size 5um
Accuracy 2um, reproducibility 10um
Tungsten wire 20um to 60um, matched to beam size
Hardware status
Wire scanners for injector tested to meet specs and calibrated
Photomultipliers with charge integrating ADCs tested
Software status
Low level EPICS
Calibration tool
Scan user interface to select 1 or more wires
Buffered acquisition linked to timing system
High level Matlab
Software for normalization with toroid and jitter correction with BPM to be completed in November
Profile analysis and emittance calculation same as for profile monitors

18. Requirements
Area
IN20
LI21
LI24
LI27
LI28
LTU
Total
Scanners 4 3 1 19

19. Distance Measurement (LVDT or similar)
Design - Mechanical
Distance Measurement (LVDT or similar)
Motor
Beam
Limit Switches

20. Current Status

21. User Interface - Operations

22. Transverse Cavity Bunch Length Measurement
TCAV in 135 MeV
Low field of 1.4 MV sufficient
Invasive measurements on OTR2, 4, S1, YAGS2
TCAV in Sector 25 at 5.9 GeV
Max field of 25 MV
Parasitic measurement with horizontal kicker and off-axis OTR
Horizontal
Kicker
Vertical
Deflecting Cavity
Off-axis
Screen
Electron
Beam

23. Injector TCAV
TCAV tested successfully at full gradient in klystron lab
3MW, 120Hz, 3us pulse
2MW, 120Hz, 3us pulse was requirement

24. Transverse Cavity Calibration
Temporal resolution limited by beta function, RF power, screen size
Calibration with TCAV phase scan
Calibration accuracy limited by phase jitter
TCAV injector: >>20 slices possible
TCAV linac: <5 slices due to limited RF, non-dedicated optics, screen resolution
Mock-up
Mock-up

25. Software Development

26. Commissioning Readiness
Redundancy in diagnostics, independent methods to determine the most important beam parameters
Before commissioning check-out of each device by physicist to verify proper functioning and correct assignment in control system