Sub-picometer dynamic measurements of a diffuse surface

Babak Saif; Perry Greenfield; Michael North-Morris; Marcel Bluth; Lee Feinberg; J. C. Wyant; Ritva Keski-Kuha

doi:10.1364/AO.58.003156

Applied Optics
Vol. 58,
Issue 12,
pp. 3156-3165
(2019)
•https://doi.org/10.1364/AO.58.003156

Sub-picometer dynamic measurements of a diffuse surface

Babak Saif, Perry Greenfield, Michael North-Morris, Marcel Bluth, Lee Feinberg, J. C. Wyant, and Ritva Keski-Kuha

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Babak Saif, Perry Greenfield, Michael North-Morris, Marcel Bluth, Lee Feinberg, J. C. Wyant, and Ritva Keski-Kuha, "Sub-picometer dynamic measurements of a diffuse surface," Appl. Opt. 58, 3156-3165 (2019)

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Abstract

Future space observatory missions are forecasting the need for sensing and controlling wavefront error and system alignment stability to picometer scale. Picometer stability performance demands precision knowledge of the mirror and metering structure materials to the same degree. A high-speed electronic speckle pattern interferometer was designed and built to demonstrate measurements of both static and dynamic responses of picometer amplitudes in materials of diffuse surface subjected to very low energy disturbances. This paper describes the details of a test to impart a dynamic disturbance of picometer scale and measure the response of a composite material. The results of the test are also reported and show conclusively that sub-picometer scale effects can be accurately measured in an open test environment outside a vacuum chamber.

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Parameter	Value
Active pixels	$1280 \times 1024$
8-bit frame rate for full array (full camera link)	506 fps
Sensor type	CMOS global shutter
Sensitivity (mono)	$10.2 \times V / (lux s)$ at 550 nm
Color depth	8 bit
Shutter time (steps)	2 μs
Shutter time range	2 μs to 1 s

Size of Region of Interest (Pixels)	Frame Rate (Frames per Second)
$880 \times 880$	850
$720 \times 720$	1000
$560 \times 560$	1400
$460 \times 460$	1800
$400 \times 400$	2250
$240 \times 240$	4000

Surface Zernike Term	First Set–8 K Runs			Second Set–21 K Runs
Surface Zernike Term	Amplitude (pm)	Standard Deviation (pm)	Probability of Null	Amplitude (pm)	Standard Deviation (pm)	Probability of Null
Z0	15.34	1.624	0.0000	13.84	3.456	0.0003
Z1	0.16	0.032	0.0000	0.12	0.062	0.1674
Z2	0.10	0.076	0.4400	0.30	0.112	0.0026
Z3	0.11	0.021	0.0000	0.10	0.037	0.1787
Z4	0.05	0.013	0.0005	0.04	0.018	0.0687
Z5	0.05	0.014	0.0049	0.04	0.020	0.0784
Z6	0.02	0.009	0.1800	0.00	0.011	0.0922
Z7	0.02	0.010	0.1200	0.01	0.012	0.8052
Z8	0.02	0.010	0.2800	0.01	0.011	0.5089
Z9	0.02	0.011	0.3100	0.04	0.014	0.0240

Surface Zernike Term	Amplitude (pm)	Standard Deviation (pm)	Probability of Null
Z0	82.87	4.548	0.0000
Z1	0.28	0.077	0.0012
Z2	1.23	0.151	0.0000
Z3	0.29	0.037	0.0000
Z4	0.05	0.018	0.0376
Z5	0.22	0.022	0.0000
Z6	0.02	0.013	0.4182
Z7	0.01	0.013	0.7045
Z8	0.06	0.015	0.0001
Z9	0.02	0.014	0.4048

Parameter	Value
Active pixels	$1280 \times 1024$
8-bit frame rate for full array (full camera link)	506 fps
Sensor type	CMOS global shutter
Sensitivity (mono)	$10.2 \times V / (lux s)$ at 550 nm
Color depth	8 bit
Shutter time (steps)	2 μs
Shutter time range	2 μs to 1 s

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Equations (5)

Applied Optics