硅镜片用于红外物镜 Silicon Elements for IR Objective Lenses-上海屹持光电技术有限公司

详细信息

Silicon Elements for IR Objective Lenses

资料下载：Download Silicon Elements for IR Objective Lenses Datasheet (PDF, 144 KB)

TYDEX produces a wide range of elements made of silicon. We ensure strong control on every step of element production, from material selection to the measurement of obtained parameters of polished elements and coating characteristics. That is especially important in the manufacturing of precision imaging systems. This type of approach to the production of a set of large silicon optics for IR objective is described below.

The objective is intended for operating in two middle IR bands: 1.6 - 3.0mm and 3.5 - 5.5 mm. Its design incorporates 17 elements: 14 meniscus and plano-convex lenses with diameters from 10 mm to 210 mm and 3 plates with dimensions to 134 x 198 mm.

When manufacturing such multi-element imaging devices two important points should be taken into consideration: transmittance of the whole system and image distortion. These parameters depend on material quality (i) and surface accuracy (ii). Below we discuss our approach to control of these parameters (we will not touch the third critical point - coating parameters).

Material selection and control

For imaging systems the right choice of material is of utmost very importance. Defects in the material can cause image distortion and violate the system operation. This is the reason why so much attention is paid to selecting the material and its control. To provide the proper quality of material, silicon ingots with special parameters (dislocation-free optical grade monocrystalline Cz-Si with high homogeneity and transparency in the working range) were grown. After a few required ingots with diameter to 219 mm were ready the quality of material (resistance homogeneity, dislocation density, transmittance in the working range) is being controlled on samples prepared from each ingot. The typical transmission curve is presented here.

Fig. 1 Silicon transmission in the 1.1 - 5.7 mm spectral range. Sample thikness is 10 mm.

Surface accuracy control

As mentioned above, the second important parameter that should be considered is surface errors. Modern equipment allows to carry out complete interferometric control of a the whole surface or any part of it. Computer data processing enables us to obtain detailed information about different kinds of errors: regular errors (astigmatism, zonal error, coma), local errors, peak-to-valley value etc. In addition, representation of errors becomes easy to interpret.

For interferometric control Fizeau scheme is applied, λ_c = 632.8 nm (HeNe laser line). Additional equipment such as telescopic expanders and measuring objectives is used if required by surface shape and radius of curvature. Evaluation of the form error of a surface is being carried out in phase mode by means of measuring the deformation of the wavefront reflected from the controlled surface compared to test reference surface. Specialised integrated software is used to create phase data arrays and their further power polynomial approximation for surface error calculations.

Here we present as examples the results of such control for 2 surfaces: 1 - concave surface of meniscus D210 mm lens, and 2 - plane surface of 198 x 134 mm plate.

Interferometric measurements of errors of meniscus lens D210 mm

Controlled surface, mm
Test area, mm
Measurement units
Reference surface

concave R = -206.99
clear aperture - central D206
microns
sphere

Regular errors:

D= .080	LX= 2.839	LY= -.013	C= 2.829	RMS(W)= .031
A= .050	FIA= .354		RMS(W-A)= .023	FA= .442
B0= -.025	RZ= .037
	RMS(W-Z)= .029	FZ= .131
B2= .149
B4= -.149
C= .110	FIC= 164.892		RMS(W-C)= .028	FC= .178

Local errors:

R= .139

RMS(M)= .015

Parameters of surface:

RMS	MIN	MAX	R	STRL	STRH
.031	-.144	.092	.237	.964	.988

X :	-1.000	.000
Y :	.000	-1.000

Fig. 2 Reconstracted wavefront topography presented at planar and 3-d plots.

Fig. 3 Interferogram of the surface.

Interferometric measurements of errors of plane parallel plate 198x134 mm

The surface undergoes measurements in 2 areas: center zone of dimensions 70 x 70 mm (approximately the area occupied by incident ray) and the whole aperture 194 x 130 mm.

Controlled surface S1
A/ Test area, mm
Measurement units
Reference surface

plane R = infinity
70 x 70
microns
plane

Regular errors:

D= .000	LX= 1.447	LY= .033	C= .964	RMS(W)= .014
A= .045	FIA= 82.986		RMS(W-A)= .010	FA= .489
B0= -.014	RZ= .023		RMS(W-Z)= .012	FZ= .235
B2= .064
B4= -.045
C= .012	FIC= 173.740		RMS(W-C)= .014	FC= .009

Local errors:

R= .076

RMS(M)= .007

Parameters of surface:

RMS	MIN	MAX	R	STRL	STRH
.014	-.035	.044	.079	.993	.998

X :	-.680	.680
Y :	.680	-.680

Fig. 4 Reconctracted wavefront topography presented at planar and 3-d plots.

B/ Test area, mm
Measurement units
Reference surface

194 x 130
microns
plane

Regular errors:

D= .000	LX= 2.811	LY= .053	C= 2.045	RMS(W)= .024
A= .104	FIA= 81.477		RMS(W-A)= .011	FA= .787
B0= -.020	RZ= .083		RMS(W-Z)= .016	FZ= .561
B2=.039
B4= .117
C= .022	FIC= 50.186		RMS(W-C)= .023	FC= .014

Local errors:

R= .077

RMS(M)= .012

Parameters of surface:

RMS	MIN	MAX	R	STRL	STRH
.024	-.036	.076	.112	.978	.993

X :	-.200	.680
Y :	.480	-.440

Reconctracted wavefront topography presented at 3-d plots

Fig. 5 Reconctracted wavefront topography presented at planar and 3-d plots.

Fig. 6 Interferogram of the surface S1.

Such thorough control on each step of production can guarantee that all parameters of the item meet specifications required by customer and that the device will operate in a proper way.